Awards

In the developing world, infections in the respiratory and intestinal tracts are major causes of sickness and death, especially among children. Vaccine delivery systems that can target respiratory or intestinal mucosal tissue and stimulate immune response there have the potential to be particularly effective against these infections. Dr. Lo's project addresses two needs: the development of vaccine delivery systems that do not require needles and the design of systems that target specific tissues in the body. Using influenza vaccination as a model, Dr. Lo and his team are working to bind vaccine to specially designed molecules that target mucosal tissue.

Vaccines that can be delivered without needles have the potential to be simpler to administer and less prone to spreading infection. Dr. Baker's team is developing a new way of preparing vaccines so that they can be given as nasal drops. These nanoemulsion-based vaccines use non-toxic lipid droplets less than 200 nanometers in diameter that are absorbed through the mucosal surfaces of the nostrils. They can be easily produced using an extrusion process available worldwide and are antimicrobial, eliminating the need for preservatives or refrigeration. The team is performing proof-of-concept, feasibility, and toxicology studies for a nanoemulsion-based vaccine for hepatitis B surface antigen. Baker (Grand Challenges in Global Health: 2005-2015 retrospective)

Many serious infections, such as the measles virus, can enter the body through inhalation. Vaccine delivery systems that can target respiratory mucosal tissue and stimulate immune response there have the potential to be particularly effective against these types of infections. Collaborating with an international group that includes the Serum Institute of India (SII), the U.S. Centers for Disease Control and Prevention (CDC), the University of Colorado, and private companies, Dr. Sievers and his colleagues at Aktiv-Dry, LLC (AD) are developing a dry-powder version of the measles vaccine that can be inhaled through a disposable plastic device. Sievers (Grand Challenges in Global Health: 2005-2015 retrospective)

Vaccine delivery systems that target specific areas of the body have the potential to be especially effective against some types of infection. For example, inhaled vaccines may better guard against respiratory diseases, such as tuberculosis, and those that commonly infect the tissues of the nose and throat, such as diphtheria. Dr. Edwards is leading a multidisciplinary team using materials science technologies combined with infectious disease, device, and toxicology expertise to reformulate tuberculosis and diphtheria vaccines into aerosol sprays that can be inhaled. The team's ultimate objective is to develop a cell-based BCG vaccine for tuberculosis and a protein antigen CRM 197 vaccine for diphtheria in the form of novel porous nanoparticle aggregate (PNAP) aerosols.

Most vaccines are delivered by injection, which increases the risk that HIV, hepatitis, and other serious diseases may be transmitted by syringes and needles that are not sterile. Dr. Alonso's team is working to develop a new generation of delivery systems that can easily and effectively carry hepatitis B vaccine through the mucosal lining of the nose. In addition, the team is evaluating whether these delivery systems and the vaccine they carry can be freeze-dried into an inhaled powder that could be stored without refrigeration.