Prizes focus attention on critical challenges to create revolutionary advances in technologies. Although grants are critical in helping researchers move forward, prizes have been shown to coalesce a community of practice, increase public engagement, and inspire new problem solvers to participate in overcoming the challenges at hand in new and effective ways.



Well-executed challenges have launched entire industries in the past, such as the Orteig Prize won by Charles Lindbergh in 1927, which transformed U.S. aviation. Among other things, good prizes can attract new capital to seemingly intractable problems, motivate top minds and non-traditional players, galvanize public demand, force regulatory reform, encourage smart risk taking, and help transcend perceived constraints.



For this challenge, the Methuselah Foundation (the New Organ Alliance's fiscal sponsor non-profit charity) and the National Aeronautics and Space Administration (NASA) entered into an agreement to help advance the State of the Art (SOA) in the tissue engineering field. It is expected that the challenge results will become part of a portfolio of technologies pushing the boundaries of this field. The Methuselah Foundation's New Organ Alliance is responsible for the development and execution of the challenge. The Challenge is incentivized by a NASA-provided prize purse not to exceed $500,000.00 (five hundred thousand U.S. dollars) paid directly by NASA to the Challenge winner(s). Prize money will be allocated into separate pools and distributed in accordance with a pre-determined method as detailed in the Challenge rules.

It is expected that this Challenge will result in game changing technologies that will enable broad ranging new research leading to capabilities to repair and replace tissues and organs damaged from all kinds of impairments. The capability to vascularize tissues has been noted as the "holy grail" of tissue engineering.



Currently, research is limited to engineering thin-walled tissues and organs such as the trachea, esophagus, and bladder. The ability to get nutrients through a blood flow into thick metabolic tissues (such as organs, not just connective tissue like tendons and cartilage) to keep them alive and functioning for long periods of time has as of yet eluded researchers.



This challenge will revolutionize our ability to create thick, metabolic tissues that can be used to advance new research on thick-walled organs such as the heart, kidneys, lungs, or liver. It will enable new tissue assays and constructs that can be used in drug testing and disease modeling. It could open up a revolution in how we handle organ damage and impairment, on the Earth. NASA's interests also include the use of those tissues for the study of environmental effects (like radiation) and testing of potential mitigation strategies needed for long term deep space missions.



Around the world, millions of people need replacement organs, and many die before finding a suitable donor. In the United States, the wait list has skyrocketed while the number of available organs has stayed relatively flat. Even those fortunate enough to find an organ in time face serious medical difficulties, often for the rest of their lives.



The growing field of regenerative medicine offers many potential solutions, but it is drastically underfunded compared to more established areas of medicine. The Vascular Tissue Challenge will enable incredible new research and development to advance the capabilities needed to significantly reduce the organ shortage.

Tissue engineering research has currently been limited to engineering thin-walled organs such as the trachea, esophagus, bladder, or connective tissues such as cartilage and ligaments. Researchers have been limited by the diffusion of nutrients into the cells. Without a capability to produce vascular networks to deliver these nutrients into thick tissues, the cells will rapidly degrade and die off. Thick-tissue vascularization will allow researchers to create tissues with active blood channels capable of delivering the nutrients the entire tissue needs.

In 2015 the Methuselah Foundation's New Organ Alliance worked with the White House Office of Science and Technology Policy and the National Science Foundation to host a Roadmapping Workshop and Roundtable on Ending the Organ Shortage. During the Roadmapping Workshop, thick-tissue vascularization was identified as one of the critical enabling challenges in tissue engineering that would be required to be overcome to produce the tissues and organs for patients in need.

NASA's long term interests include the use of vascularized tissues for the study of environmental effects (like radiation) and testing of potential mitigation strategies needed for long term deep space missions. The Challenge could potentially advance research on human physiology, fundamental space biology, and medicine taking place both on the Earth and the ISS National Laboratory. Research has demonstrated potential enabling benefits of microgravity on tissue engineering technologies. Specifically, new technology innovations may enable the growth of de novo tissues and organs in orbit which may address the risks related to traumatic bodily injury, improve general crew health, and enhance crew performance on future, long-duration spaceflight missions.

NASA's Centennial Challenges Program partners with non-profit organizations (called Allied Organizations) to execute competitions in technology areas of interest to NASA and the Nation. Interested no-profit organizations with expertise in targeted areas provide NASA proposals for partnerships. Through its New Organ Alliance, the Methuselah Foundation has critical expertise in Tissue Engineering, prize development and operations that served as the basis of NASA's selecting Methuselah as the Allied Organization for this challenge. In 2014, NASA and the Methuselah Foundation's New Organ Alliance began exploring the possibility of creating a tissue engineering challenge that would be of interest to both the space agency and our healthcare industry here at home. In 2016, a Space Act Agreement was signed between NASA and the Methuselah Foundation for the development of the Vascular Tissue Challenge.

Although NASA is currently the sole prize sponsor, providing the entire $500,000 prize purse, the Methuselah Foundation's New Organ Alliance maintains close connections with many leaders at the NIH and other federal agencies. Experts from NIH, DoD, HHS, and others have been consulted in the development of the prize rules, and may be participating in the official Judging Committee. The New Organ Alliance also encourages collaboration on this and other prizes, teams competing for the prizes are provided with advice and guidance on potential research grant opportunities that may be used to help facilitate the development of their technology for this challenge. Additionally, the challenge requires that participants adhere to NIH guidelines for the creation and handling of their tissues.

The New Organ Alliance's Scientific Advisory Board reviewed the inclusion of many different types of tissues for the Vascular Tissue Challenge. One key requirement was the need to develop tissues for thick-walled organs such as the heart, liver, lung, and kidneys. Additionally muscle was included in this group because of the widely varying size of muscle tissues. Connective tissues such as cartilage and tendons do not require as much blood supply of nutrients to remain functioning. Therefore, the technology hurdle here was considered to be already achieved. The development of new bone tissue was in somewhat of a grey area, and has not currently been included in the allowable tissues. However, researchers can petition the Judging Committee to include additional types of tissue in the prize, if they can show that the technology hurdle remains due to an inability to produce vascular flow of nutrients to the entire tissue.

A review panel of experts from the New Organ Alliance's Scientific Advisory Board, and additional experts across the Tissue Engineering industry provided insight and guidance on how to evaluate a team's tissue to determine if it actually has produced viable integration of a vascular network capable of delivering nutrients throughout the tissue, and producing functions similar to those of a healthy, native organ of the same type. The criteria selected were determined to allow the judging committee adequate review of the team'trials to determine a winner based on these criteria. Evaluation criteria were posted for public comment for 6 weeks in March and April 2016.

Judges are selected from the New Organ Alliance's Scientific Advisory Board, the NASA tissue engineering community, and other researchers who have demonstrated their expertise in the tissue engineering fields.

One goal for this challenge is to begin to expand the knowledge of the potential enabling benefits of spaceflight on tissue engineering. Another goal is to use the tissues developed from this Challenge to support human exploration of space as well as to investigate the potential role of microgravity to develop larger and more medically useful engineered tissues for terrestrial as well as NASA benefit. Teams are asked to create a spaceflight experiment concept to draw the connection between spaceflight research opportunities and the laboratories who may be interested in future experiments on the International Space Stations National Laboratory. The Center for the Advancement of Science in Space (CASIS) will be using these concepts to evaluate teams that may receive an additional award to actually take an experiment that would advance their research in tissue engineering to the Space Station.

All requests for information about prize operations, team registration, or other activities related to the prize should be directed to the New Organ Alliance at: info@neworgan.org. All inquiries related to NASA's involvement in the prize should be directed to Monsi Roman, Director of the NASA Centennial Challenges Program: monsi.roman@nasa.gov