News: 2009

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October 13: NIBIB Announces Regional Grantsmanship Seminar – November 19, 2009

The NIBIB invites all interested colleagues to attend a regional Grantsmanship Seminar on Thursday, November 19, 2009. This event will be hosted by the University of Washington in Seattle.

This Grantsmanship Seminar is intended to provide an overview of NIBIB funding opportunities and the NIH application, review, and grant-making processes and policies. We invite faculty, researchers, students, and others interested in research opportunities in bioengineering, biomedical imaging, and research training opportunities at the NIH to attend.

The one-day program will feature presentations from NIBIB science program and scientific review staff on the following topics:

• Introdcution and Status of the NIBIB
• NIH General Overview
• Overview of NIBIB Research Areas and Opportunities
• NIBIB Research Training and Career Development Opportunities
• NIH Peer Review Process and Grant Application

 

If you are interested in attending the Grantsmanship Seminar, please register here: http://www.uweb.engr.washington.edu/NIBIB/. The registration fee is $69 for general attendance and free for all currently enrolled students and postdoctoral fellows. Early registration is advised as space is limited and on-site registration (if available) will be more expensive.

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September 14: NIBIB Grantee, PATH, Awarded Hilton Humanitarian Prize – World's Largest Humanitarian Prize

PATH (Program for Appropriate Technology in Health), an international nonprofit organization that uses innovative technologies and solutions to solve global health problems, has been selected to receive the 2009 Conrad N. Hilton Humanitarian Prize of $1.5 million. The Conrad N. Hilton Foundation presents the annual award, the world’s largest humanitarian prize, to an organization that is significantly alleviating human suffering worldwide. The prize will be presented on September 21 in Washington, D.C. PATH was one of more than 200 nominees for the 2009 Hilton Humanitarian Prize.

The 2009 Hilton Humanitarian Prize will help promote PATH’s mission and new initiatives to improve the health of people around the world by advancing technologies, strengthening systems, and encouraging healthy behaviors. PATH currently works in more than 70 countries and is leading efforts in identifying, introducing and scaling up affordable technology solutions to break long-standing cycles of poor health in developing countries. A Seattle-based organization, PATH has state-of-the-art laboratories and product development facilities, where more than 85 cutting-edge technologies have been developed in the areas of technology development, maternal and child health, reproductive health, vaccines and immunization, and emerging and epidemic diseases.

Included in PATH’s realm of technology development, is the development of appropriate point-of-care (POC) diagnostic tests designed for low-resource settings, especially in developing countries. Low-cost POC tools are needed in developing countries where diagnostic capabilities are minimal, inadequate, or even nonexistent. POC testing refers to the timely provision of diagnostic testing and therapy at the point-of-care that can reliably be used by a range of healthcare providers or by patients themselves in decentralized (i.e., non-hospital) settings.

The National Institute of Biomedical Imaging and Bioengineering (NIBIB) funds the Center for Point-of-Care Diagnostics for Global Health (http://www.path.org/dxcenter/) as part of a POC Technologies Research Network to facilitate the development and application of these technologies to health care. NIBIB funded four Centers within the Network, each with a different POC diagnostic focus but bound through common goals and objectives.

Read more about the PATH Hilton Humanitarian Prize at: http://www.hiltonfoundation.org/press_release_details.asp?id=72.

Read more about the Center to Advance POC Diagnostics for Global Health at:http://www.nibib.nih.gov/Research/POCTRN/GlobalHealth.

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August 17: NIBIB Invests in Interdisciplinary Graduate Research Training

Phase II of the HHMI-NIBIB Interfaces Initiative for Interdisciplinary Graduate Research Training

The National Institute of Biomedical Imaging and Bioengineering (NIBIB), part of the National Institutes of Health, announced today that it has awarded ten Phase II interdisciplinary research training grants totaling $16 million over five years. These training grants will provide sustained support for interdisciplinary research training that integrates the biomedical sciences with the physical sciences and engineering.

These awards will increase the number of interdisciplinary researchers working at the intersection of the biological and physical sciences and will transform institutional programs to support interdisciplinary training. The awards represent the second phase of the Howard Hughes Medical Institute (HHMI)-NIBIB Interfaces Initiative for Interdisciplinary Graduate Research Training, a collaborative training program that was developed jointly by both institutions with the goal of increasing interdisciplinary training opportunities. Funding for Phase I of the Interfaces Initiative was provided by HHMI, which awarded $10 million in three-year grants to ten institutions to jump-start the development of new and innovative ways to train interdisciplinary scientists. These awards provided flexible support for faculty recruitment, administrative staff, curriculum development, and program evaluation activities. The present Phase II awards provide support for research training of predoctoral students in interdisciplinary research.

"Developing new approaches to interdisciplinary training is vitally important in preparing the next generation of scientists for the complex medical challenges ahead," said Roderic I. Pettigrew, NIBIB director. "NIBIB is delighted to have partnered with HHMI in creating this innovative program, which was crafted specifically to provide biomedical education and research training that integrates the physical and life sciences. Students who are a product of this program should be fluent in the science at the interface of these interdependent but previously separately taught fields."

"We are excited to see this program continue on into phase II. The HHMI/NIBIB partnership has enabled each institution to do what it does best, working together to address the common goal of producing new scientists at the interfaces between physical sciences, mathematics and life sciences," said Peter J. Bruns, HHMI’s vice president for grants and special programs. "HHMI was able to support the establishment of these programs and now NIH is providing the long term student support that is absolutely essential for programs that bridge multiple academic compartments."

The programs selected for award will link the educational and research training missions of multiple schools and departments, including biology, chemistry, computational mathematics, engineering, and physics. These programs feature unique and innovative activities, such as boot camps, team challenges, interdisciplinary courses and laboratories, courses on communication and collaboration, dual or team-based research mentoring, and interdisciplinary rotations, retreats, and seminars. In addition, they include plans for identifying and disseminating best practices in interdisciplinary educational and research training to the broader extramural community.

The phase II awardees are:

• Brandeis University, Waltham, MA – Quantitative Biology: a Graduate Curriculum Linking the Physical and Biomedical Sciences
• Keck Center of the Gulf Coast Consortia, Houston, TX (Baylor College of Medicine, Rice University, University of Houston, the University of Texas Health Science Center at Houston, University of Texas MD Anderson Cancer Center, and University of Texas Medical Branch at Galveston) – Nanobiology Interdisciplinary Graduate Training Program
• Northwestern University, Evanston, IL – Interdisciplinary Graduate Education in Movement and Rehabilitation Sciences
• University of California, Irvine – Mathematical, Computational and Systems Biology
• University of California, San Diego – Training in Multi-scale Analysis of Biological Structure and Function
• University of California, San Francisco – Integrated Program in Complex Biological Systems (ipCBS)
• University of Chicago – Graduate Program in Biophysical Sciences
• University of New Mexico, Albuquerque – Program in Interdisciplinary Biological and Biomedical Science (PiBBS)
• University of Pennsylvania, Philadelphia – Training Program in Biomedical Imaging and Informational Sciences
• University of Pittsburgh/Carnegie Mellon University – Interdisciplinary, Integrative, Inter-university PhD Program in Computational Biology

The Howard Hughes Medical Institute plays a powerful role in advancing scientific research and education in the United States. Its scientists, located across the country and around the world, have made important discoveries that advance both human health and our fundamental understanding of biology. The Institute also aims to transform science education into a creative, interdisciplinary endeavor that reflects the excitement of real research. For more information, visit www.hhmi.org/about/.

NIBIB, a component of NIH, is dedicated to improving health by bridging the physical and biological sciences to develop and apply new biomedical technologies.

The National Institutes of Health (NIH) – The Nation's Medical Research Agency – includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. It is the primary federal agency for conducting and supporting basic, clinical and translational medical research, and it investigates the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit www.nih.gov.

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July 1: Imaging Technique Allows Researchers to Monitor Protein Changes in Mouse Tumors

A new imaging technique can monitor, in living mice, the HER2 protein found in above-normal amounts in many cases of breast cancer as well as some ovarian, prostate and lung cancers. This new approach, once validated in mice and pending further experiments, could provide a real-time noninvasive method for identifying tumors in humans who express HER2 and who would be candidates for targeted therapy directed against this protein. It may also provide real-time information that will help clinicians optimize treatment for individual patients. The study, published in the July 2009 issue of The Journal of Nuclear Medicine, was conducted by researchers at the National Cancer Institute (NCI) and the National Institute of Biomedical Imaging and Bioengineering, both parts of the National Institutes of Health.

The HER2 protein is overexpressed (produced at higher-than-normal levels) in approximately 20 percent to 25 percent of breast cancers. Tumors that overexpress HER2 are more aggressive and more likely to recur than tumors that do not overexpress the protein. Targeted therapies directed against HER2 can slow or stop the growth of tumors that overexpress it.

Currently, HER2 expression is measured in biopsy specimens - that is, in tumor samples that have been removed from the body. However, expression of HER2 in these samples may not accurately represent HER2 expression in the tumor as a whole. Moreover, follow-up biopsies are not routinely performed after the initial diagnosis, and there are no means to evaluate how long a targeted therapy takes to reach its target, how effective it is, and how long its effects last.

In this study, the research team used an imaging compound that consists of a radioactive atom (fluorine-18) attached to an Affibody molecule, a small protein that binds strongly and specifically to HER2. Affibody molecules, developed by Affibody AB, Bromma, Sweden, are much smaller than antibodies and can reach the surface of tumors more easily. The radioactive atom allows the distribution of the Affibody molecules in the body to be analyzed by positron emission tomography (PET) imaging.

The research team first used the radiolabeled Affibody molecule to visualize tumors that expressed HER2 in mice. The mice were injected under the skin with human breast cancer cells that varied in their levels of HER2 expression, from no expression to very high expression. After three to five weeks, when tumors had formed, the mice were injected with the Affibody molecule and PET images were recorded. The levels of HER2 expression as determined by PET were consistent with the levels measured in surgically removed samples of the same tumors using established laboratory techniques.

To determine whether their method could be used to monitor possible changes in HER2 expression in response to treatment, the team next injected the Affibody molecule into mice with tumors that expressed very high or high levels of HER2 and then treated them with the drug 17-DMAG, which is known to decrease HER2 expression. PET scans were performed before and after 17-DMAG treatment. The researchers found that HER2 levels were reduced by 71 percent in mice with tumors that expressed very high levels of HER2 and by 33 percent in mice with tumors that expressed high levels of HER2 in comparison with mice that did not receive 17-DMAG. The researchers confirmed these reductions by using established laboratory techniques to determine the concentrations of HER2 in the tumors after they were removed from the mice.

"Our work shows that PET imaging using Affibody molecules was sufficiently sensitive to detect a twofold to threefold decrease in HER2 expression," said senior author Jacek Capala, Ph.D., of NCI's Center for Cancer Research. "Therefore, PET imaging may provide a considerable advantage over current methods. Our technique would allow a better selection of patients for HER2-targeted therapies and also early detection of tumors that either do not respond to or acquire resistance to these therapies."

"This approach might easily be extended to forms of cancer other than breast cancer," continued Capala. "Because Affibody molecules may be selected to target specific cell proteins, similar compounds can be developed to target proteins that are unique to other types of tumors."

For more information on Dr. Capala's research, please go to: http://ccr.cancer.gov/staff/staff.asp?profileid=9891.

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June 30: NIBIB Quantum Grantee Mehmet Toner and Team Receive National Stand Up to Cancer Grant

A research team headed by Drs. Mehmet Toner, Ph.D. and Daniel Haber, M.D., Ph.D., of the Massachusetts General Hospital Cancer Center, has been awarded a $15 million research grant from the proceeds raised by the Entertainment Industry Foundation during their landmark Stand Up to Cancer (SU2C) telethon. The Foundation, established by media and entertainment industry leaders to raise cancer awareness and accelerate developments in cancer research, raised over $100 million during their first telethon, which was aired simultaneously by ABC, CBS, and NBC in September 2008.

The SU2C grant will help accelerate research and development of the Circulating Tumor Cell (CTC) microchip, which was initiated with National Institute of Biomedical Imaging and Bioengineering (NIBIB) Quantum Grant (QG) funds in 2007. The size of a mere microscope slide, with great sensitivity that allows the detection of one at-large cancer cell out of a billion blood cells, the CTC chip sorts out and traps migrating tumor cells gently enough to also maintain their viability, which is key to further analysis that gives clues that can contribute to decisions on cancer treatment.

Toner explains how QG strategies set the research bar higher, but also promote the proper environment for success. "The Quantum Grants take a major medical problem where engineering could have great impact, and they put together a multidisciplinary team to tackle the problem. It requires people who are working closely together, and it requires us to take on a bigger challenge than we would ordinarily."

The "one-two punch" of CTC microchip research success has thus far been realized through the tandem impact of QG funds and the NIBIB-funded BioMEMS (Biomicroelectromechanical Systems) Resource Center, which, in Toner’s words, "…has been a unique environment nurturing the translation of this device from a ‘cool technology’ phase to ‘real technology’ phase with great potential for impact at the patient’s bedside."

Toner explains, "Getting technology to people’s bedside is not an easy thing to do. The [BioMEMS] experience has been educational for me, and very beneficial. It has impacted my own research group to become more translational, and we do it better than we could in the past. You have to step forward into full-scale collaboration to make strides forward translationally."

Toner also appreciates the wisdom behind NIBIB’s requirements for end-user collaboration with the Resource Center. "In order to get continued funding, we have to be able to disseminate the technology. This is extremely critical to development, because by working together with end users, we can really sharpen the functionalities and specifications of the technology."

Highlighting the mounting challenges of today’s multidisciplinary research, he continues, "The research problems we are working on are more and more complex. You need to integrate with collaborators on a day-to-day basis so that they can help you think about problems and issues in areas where you’re not an expert, and create an environment where you actually think together – morph together – sharing information, access, and also sharing credit."

The NIBIB fosters interdisciplinary research and the translation of research to clinical application. The CTC microchip research project is consistent with the NIBIB mission in technology development and the philosophy of accelerating technology application.

Read more about the CTC microchip Quantum Grant.

...and more about the SU2C grant at:

• http://su2c.standup2cancer.org/node/3531
• http://www.mgh.harvard.edu/cancer/news/circulating_tumor_cells.aspx
• http://www.mgh.harvard.edu/cancer/

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February 6: Announcing NIBIB Forum for Technology Translation: The Role of Public-Private Partnerships in the Development and Translation of in vitro Diagnostics

Program and Logistics (Adobe PDF 18K)

The NIBIB will host a forum on the role of public-private partnerships in the development and translation of in vitro diagnostic technologies on April 2, 2009, in Seattle, WA. This will be the first of a series of forums on technology translation through which the NIBIB hopes to achieve the following goals:

• to improve the process of developing collaborations between the NIBIB and public/private sector partners
• to identify best practices for accelerating the clinical translation of new medical technologies
• to highlight technology development programs and research funded by the NIBIB.

The technology focus for this forum will be on in vitro diagnostics with applications in point-of-care settings. Specifically, development efforts in multiplexed diagnostics will be highlighted in this meeting. The program will consist of presentations by NIBIB grantees as well as by representatives from industry and the FDA. Key topics of discussion will be:

• What are challenges and resource gaps in the clinical translation process including development and regulatory issues?
• How to capture and leverage best practices through an exchange of lessons-learned examples of successful or unsuccessful commercialization ventures.
• Identification and development of enabling resources such as performance and validation standards.

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January 12: NIBIB-RSNA RadLex Ontology Project

RadLex is supported both by the National Institute of Biomedical Imaging and Bioengineering (NIBIB) and by the cancer Biomedical Informatics Grid (caBIG) project of the National Cancer Institute (NCI).

The purpose of the NIBIB supported RSNA RadLex Ontology project is to provide a uniform source of terms and concepts for indexing and retrieving a variety of imaging information sources, such as imaging research databases, educational materials, and clinical imaging reports.

When complete, the RadLex Ontology will be capable of describing the salient aspects of an imaging examination, including modality, technique, visual features, anatomy, findings, and pathology. The RadLex Ontology will be available for use by a wide variety of software tools and web-based information resources, including major NIH bioinformatics projects, e.g. caBIG, BIRN, CTSA.

This project creates the RadLex Ontology of interconnected radiology concepts from the list of RadLex terms in different domains, such as Cardiovascular, Musculoskeletal, Neuroradiology, Abdominal, Pediatric, Thoracic Systems, etc.

NIBIB-RSNA RadLex Ontology project leverages the current RSNA RadLex effort. The RadLex project has enlisted the collaboration of other radiology organizations, including RSNA and the American College of Radiology (ACR), to develop a comprehensive radiology lexicon. It has been designed to satisfy the needs of software developers, system vendors, and radiology users by adopting the best features of existing terminology systems. The RadLex terms have mapped to SNOMED-CT of the College of American Pathologists (CAP). It will also be as part of the DICOM Content Mapping Resource.

RSNA has aggressively promoted RadLex ontology to RSNA members at the RSNA annual meeting each fall. The RadLex ontology has been disseminated through RadLex web site, BioPortal web site, the National Center for Biomedical Ontology, the caBIG, and the NCI Metathesaurus. RadLex Ontology has been adopted by commercial companies, academia, and societies.

On the RSNA RadLex web site (http://www.rsna.org/RadLex/), it states: “RadLex is supported both by the National Institute of Biomedical Imaging and Bioengineering (NIBIB) and by the cancer Biomedical Informatics Grid (caBIG) project of the National Cancer Institute (NCI).”

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