Since the 2001 anthrax attacks, members of the biosecurity community and US government officials have expressed a growing sense of alarm at the threat of a biological attack.  The Commission on the Prevention of Weapons of Mass Destruction Proliferation and Terrorism recently predicted that a terrorist attack involving WMD is likely to take place by 2013 and identified biological terrorism as the most likely contingency.  To counter this threat, increasing emphasis has been placed on the role of microbial forensics in deterring an attack. New infrastructure has been established by the US government to develop capabilities to identify the source of a pathogen used in an attack and identify the perpetrators. However, many open questions remain about the potential efficacy of this approach both from a technological capabilities standpoint and from a deterrence perspective.

Existing technologies can be borrowed from molecular biology to identify elements in a pathogen's DNA, which could help investigators trace it back to a specific source strain. However, these tools are limited, and new methods should be developed to increase confidence in microbial forensics analyses. Moreover, a comprehensive genome database of pathogen strains is necessary for an effective investigation in the event of an attack. Who will cover the costs of sequencing pathogen genome strains to generate such a database? Will there be obstacles to gaining cooperation from academic and government facilities within the United States and internationally?  In the best-case scenario, advances in microbial forensics could enable us to identify the source of a biological attack; would these capabilities effectively deter non-state actors? These questions must be addressed to determine the extent to which microbial forensics programs can meet their stated goals.

Jaime Yassif is a doctoral candidate in the Biophysics Group at UC Berkeley. She is conducting her thesis research in the Liphardt lab, where she studies the dynamics of RNA-binding proteins using a single-molecule technique called plasmon rulers.

Prior to her graduate work, Ms. Yassif worked for several years in science and security policy and arms control.  She began as a research assistant at the Federation of American Scientists, where she contributed to the writing of Senate Foreign Relations Committee testimony on radiological weapons and authored a piece on radiological decontamination in Defense News. She then worked as a program officer at the Nuclear Threat Initiative, where she provided support for the organization's four key program areas-Russia/New Independent States, Biological, Regional and Communications-and managed the organization of an international workshop on Global Best Practices in Nuclear Materials Management. This was followed by a fellowship to study the Chinese nuclear posture at Tsinghua University in Beijing.

Ms. Yassif holds an MA in Science and Security from the War Studies Department at King's College London, where she wrote her thesis on verification of the Biological Weapons Convention.  She received her bachelor's degree in Biology from Swarthmore College. Ms. Yassif is former president of the student-run Science, Technology and Engineering Policy group at UC Berkeley and a member of Women in International Security.

Martha Crenshaw is a senior fellow at the Center for International Security and Cooperation and the Freeman Spogli Institute, and professor of political science (by courtesy). Her current research focuses on why the United States is the target of terrorism, the effectiveness of counter terrorism policies, and mapping terrorist organizations. Professor Crenshaw served on the Executive Board of Women in International Security and chaired the American Political Science Association (APSA) Task Force on Political Violence and Terrorism. She was a Guggenheim Fellow in 2005-2006. Her edited book, The Consequences of Counterterrorism in Democracies, is being published by the Russell Sage Foundation.

Abstract
One of the biggest themes of the 21st century is interconnection -- specifically, the interconnection of people and data.  These interconnections can change everything about how we see the world, how the world sees us, and how we work together.  Where some people might see "big brother," I see empowerment -- empowerment of groups and individuals to improve quality of life and reduce our impact on the planet. 

Megan Smith oversees teams that manage early-stage partnerships, explorations and technology licensing. She also leads the Google.org team, guiding strategy and developing new partnerships and internal projects with Google's engineering and product teams. She joined Google in 2003 and has led several of the company's acquisitions, including Keyhole (Google Earth), Where2Tech (Google Maps), and Picasa. She also co-led the company's early work with publishers for Google Book Search. Previously, Megan was the CEO and, earlier, COO of PlanetOut, the leading gay, lesbian, bisexual and transgender online community. Under her leadership, PlanetOut grew tenfold in reach and revenue. Prior to that, Megan was at General Magic for six years working on handheld communications products and partnerships. She also worked in multimedia at Apple Japan in Tokyo.

Over the years, Megan has contributed to a wide range of engineering projects, such as designing an award-winning bicycle lock; working on a space station construction research project that eventually flew on the U.S. space shuttle; and running a field-research study on solar cookstoves in South America. She was also a member of the MIT-Solectria student team that designed, built, and raced a solar car in the first cross-continental solar car race, covering 2000 miles of the Australian outback. She was selected as one of the 100 World Economic Forum technology pioneers for 2001 and 2002.

Megan holds a bachelor's degree and a master's degree in mechanical engineering from MIT, where she now serves on the board. She completed her master's thesis work at the MIT Media Lab.

Summary of the Seminar
Megan Smith, Vice President, New Business Development and General Manager, Google.org., argued that greater interconnectedness achieved by information technology is a major liberating force in the world. Whether it is aiding the coordination of protests or increasing transparency of governments, the exchange of information has huge benefits. This is not a new phenomenon. In places where people have been able to exchange information easily, social progress has followed. Megan cited the example of Seneca Falls, New York where the canal system allowed for extensive communication; it became significant in both the women's rights and abolition movements.

While a large proportion of the world is benefiting from greater interconnectedness, Africa still lacks the infrastructure to take full advantage. Submarine fiber optic cables are necessary for quick and cheap internet cables and many African countries, particularly in the east, are not connected to these, relying instead on satellites. This is likely to change over the next few years, bringing great potential for further development.

The mission of Google.org is to use technology to drive solutions to global challenges such as climate change, pandemic disease and poverty. The organization was set up as part of a commitment to devote approximately one percent of Google's equity plus one percent of annual profits to philanthropy, along with employee time.  Google.org now places its strategic focus on those projects that can leverage the resources of Google staff, particularly its engineers.

Current projects that harness the power of information include:

• Google Flu Trends: This uses aggregated Google search data to estimate flu activity up to two weeks earlier than traditional methods. This system has almost 90% accuracy in real time flu prediction and is therefore an extremely useful tool for health delivery agencies. It is now being used in 30 countries. Google is also starting to work in Cambodia to collect data around SARS.
• Google Power Meter provides a system for consumers to understand their in-home energy use and to take steps to reducing this. The Meter receives information from utility smart meters and in-home energy management devices and visualizes this information on iGoogle (a personalized Google homepage).The premise underlying this project is that greater information is going to be crucial to tackling climate change and consumers ought to be able to be empowered to make informed decisions about their energy use.
• Disaster relief: In response to the Haitian earthquake, a team of engineers worked with the U.S. Department of State to create an online People Finder gadget so that people can submit information about missing persons and to search the database. Google Earth satellite images have also been used to document the extent of damage.

This talk will address alternative options for European ballistic missile defense, including the now cancelled Polish-Czech option and the recently announced Obama plan for a phased deployment of Standard Missile 3 interceptors in and around Europe. This talk will also address recent Iranian progress in developing medium-range ballistic missiles and possible missile defense cooperation with Russia.

Dean Wilkening is a Senior Research Scientist at the Center for International Security and Cooperation at Stanford University. He holds a Ph.D. in physics from Harvard University and worked at the RAND Corporation prior to coming to Stanford. His major research interests include nuclear strategy and policy, arms control, the proliferation of nuclear and biological weapons, bioterrorism, ballistic missile defense, and energy and security. His most recent research focuses on the broad strategic and political implications of ballistic missile defense deployments in Northeast Asia, South Asia and Europe. Prior work focused on the technical feasibility of boost-phase ballistic missile defense interceptors. His recent work on bioterrorism focuses on understanding the scientific and technical uncertainties associated with predicting the outcome of hypothetical airborne biological attacks and the human effects of inhalation anthrax, with the aim of devising more effective civil defenses. He has participated in, and briefed, several US National Academy of Science committees on biological terrorism and consults for several US national laboratories and government agencies.

Abstract:  In this era of catastrophic terrorism and heightened concerns about pandemic influenza and other emerging diseases, unprecedented resources have been allocated to improving medical and public health emergency preparedness.  Investments in such preparedness, however, can impose significant opportunity costs, particularly when the investments are focused on improving consequence management capabilities.  Enhancing preparedness and response capabilities in economically efficient, proportionate, and politically sustainable ways thus becomes a critical component of any longterm effort to address the threats we face.  Dr. Hatchett will speak about the challenges of developing medical countermeasure for CBRN threats and preparing communities for infectious disease emergencies, using these examples to raise more general issues about the relative benefits of specific v. "broad-spectrum" strategies and countermeasures, decision-making under conditions of uncertainty, and our efforts to "get ready" for nuclear terrorism and pandemic influenza.

Dr. Hatchett is Associate Director for Radiation Countermeasures Research and Emergency Preparedness at the National Institute for Allergy and Infectious Disease, overseeing a program that develops drugs and devices to prevent or mitigate the effects of radiation exposure. 

In 2005-06, he served as Director for Biodefense Policy at the White House Homeland Security Council, where he was a principal author of the Implementation Plan for the National Strategy for Pandemic Influenza and helped set policy and devise strategies to mitigate the consequences of a pandemic.  Dr. Hatchett previously served as Senior Medical Adviser in the U.S. Department of Health and Human Services (HHS) Office of Public Health Emergency Preparedness, where he worked on a wide range of biodefense issues, including the delivery of mass prophylaxis to urban populations, the development of disease containment strategies, and the role of modeling in the formulation of public health policy. 

Dr. Hatchett completed his undergraduate and medical educations at Vanderbilt University, an internship and residency in Internal Medicine at New York Hospital - Cornell Medical Center, and a fellowship in Medical Oncology at the Duke University Medical Center.