This CDC-developed technology is an aerosol preconcentration unit (APU) designed for use with spectroscopic detection techniques, including emission, Raman, or infrared spectroscopies. Most existing pulsed microplasma techniques, such as laser-induced breakdown, for aerosols rely mainly on filter-based collection and suffer from poor accuracy, precision, and detection limits and require long sample collection times.

CDC researchers have developed a novel acoustic whole body plethysmograph (AWBP) that allows measurement of tidal volume in lab animals, independent of gas compression in the lung. This system provides particular advantages over the traditional whole body plethysmograph (WBP) when measuring model animals with increased gas compression due to increased airway resistance or increased acceleration in the breathing pattern.

This CDC-developed technology entails a system for monitoring and assessing the risk of auditory damage from exposure to impulse noise, such as noise created by construction machinery and firearms. Noise dosimeters have been used extensively over the past two decades to document personal exposure to noise and assure workplaces comply with permissible noise exposure levels. However, due to older methods of calculating "noise dose," current noise dosimeters often inaccurately determine the risk of an impulse event.

CDC researchers have developed the Portable Exposure Assessment System (PEAS), a field-based, remotely deployed tool to monitor and provide early warning of working conditions that have a high likelihood of musculoskeletal injury. PEAS is a noninvasive, real-time, instrument-based system. Sensor technology simultaneously measures and collects data regarding the body loads and awkward postures imposed by package handling as well as driving-related, low-frequency vibrations.

This CDC-developed technology describes a novel ergonomic device that supports a portion of the worker's weight while kneeling, relieving the knee pressure and pain common to many manual labor occupations. Unfortunately, many of the devices that have been used in the past to relieve pressure on the knees are bulky, heavy, and of questionable durability.

This CDC-developed technology entails a nucleic acid-based HIV-2 in vitro diagnostic assay that is well-suited for use in mobile testing units/vehicles or resource-limited settings, for example, many areas of West Africa. Because HIV-2 requires unique treatment regimens, accurate, early diagnosis is crucial for effective care and directing treatment. Recently, new HIV testing recommendations have been proposed for laboratory settings, which include the use of a HIV-1/HIV-2 discriminatory assay.

CDC scientists have developed a novel enzyme immunoassay for the simultaneous detection of hepatitis C virus (HCV) core antigen and circulating HCV antibodies. Serological testing procedures for HCV circulating antibodies are well established. There is, however, a window of time between HCV infection and seroconversion that generates an opportunity for false negative results. This period varies from two months in immunocompetent subjects to six to twelve months in immunodeficient patients.

CDC researchers have developed a potent immunogenic enhancer polypeptide useful for improving flavivirus vaccines. Flaviviruses such as dengue virus (1, 2, 3 and 4), Japanese encephalitis virus, Murray Valley encephalitis virus, St. Louis encephalitis virus, yellow fever virus and tick-borne encephalitis virus are a great burden on public health. This technology describes an identified CD4+ T cell epitope occurring within the E-glycoprotein of West Nile virus and methods of using this polypeptide to increase vaccine immunogenicity in monovalent vaccines.

Currently available identification methods for antigen-specific antibodies require live pathogens, antisera (that are only available for a limited number of species), and species-specific secondary antibodies (also a limited resource). Thus, detection or surveillance of pathogens in wild avian species or zoo animals, for example, is complex and cumbersome.

Upon intranasal vaccination, live attenuated influenza vaccine (LAIV) viruses may replicate within the nose for several days. Current clinical diagnostic tests cannot distinguish between LAIV viruses and multiple influenza viruses in recently inoculated patients that present with respiratory symptoms. This poses a problem for the diagnosis and treatment of patients with respiratory symptoms, as these symptoms may not be caused by influenza. CDC researchers have developed a real-time RT-PCR assay to detect the presence of LAIV viruses.