Mosquitoes are responsible for spreading many viruses that can make people sick, including dengue, Zika, chikungunya, yellow fever, and more. The Centers for Disease Control and Prevention's (CDC's) new autocidal gravid ovitrap (AGO) mosquito trap is an inexpensive, simple-to-assemble, and easy-to-maintain trap that targets female mosquitoes looking for a place to lay eggs. The current trap model stands 18 inches (45cm) tall and is made of a 5-gallon (18L) bucket. The AGO trap's unique design lures mosquitoes by using water and an all-natural, organic hay attractant.

The cleavage of sphingoid base phosphates by sphingosine-1-phosphate (S1P) lyase to produce phosphoethanolamine and a fatty aldehyde is the final degradative step in the sphingolipid metabolic pathway. Researchers at NIH injected rabbits with the C-terminal peptide of the mouse S1P lyase — 551-TTDPVTQGNQMNGSPKPR-568 — to develop an antibody that can be used in western blotting to study this pathway.

Two isoforms of sphingosine kinase, sphingosine kinase 1 (SphK1) and sphingosine kinase 2 (SphK2), convert sphingosine to sphingosine 1-phosphate (S1P) in mammalian cells. While the importance of SphK1 has been known for some time, information about SphK2 is still being revealed. Therefore, researchers at NIH have developed an antibody against mouse SphK2, which can be used to further understand the role of this enzyme.

Traumatic Brain injury (TBI) often results from head impact and is a major cause of death and disability. Brain injuries vary in severity and can be associated with hemorrhaging, swelling, inflammation, and death of brain tissue. Inventors at NINDS developed a novel approach to treating brain injuries that involves transcranial application of small molecules.

Due to the disorganized nature of blood vessels that run through tumors, chemotherapeutic agents often fail to penetrate tumors and kill cancer cells at the tumor’s center. This can lead to ineffective chemotherapeutic treatments, because tumors can quickly grow back if the entire tumor is not destroyed. NIH researchers have developed a therapeutic agent that solves this problem facing current chemotherapy treatments.

This technology relates to a method of generating artificial compositions that can be used as positive controls in a genetic testing assay, such as a diagnostic assay for a particular genetic disease. Such controls can be used to confirm the presence or absence of a particular genetic mutation. The lack of easily accessible, validated mutant controls has proven to be a major obstacle to the advancement of clinical molecular genetic testing, validation, quality control (QC), quality assurance (QA), and required proficiency testing.

Our technology describes unique genetic signatures in patients with digestive diseases and liver disorders. Using comprehensive analysis of 735 microRNAs and 19,000 mRNAs, we have identified a unique set of microRNAs and/or mRNAs which predict disease phenotypes in patients with digestive and liver disorders. The identification of such point-of- care genetic signatures is significant for both personalized biomarkers and novel targeted biotherapeutics. These microRNAs and mRNAs function either together or separately thus modulating protein expressions in one or more signaling pathways.

Many potential nucleic acid therapeutics have not transitioned from the research laboratory to clinical application in large part because delivery technologies for these therapies are not effective. Most nucleic acid delivery technologies are lipid-based or positively charged and require chemical or physical conjugation with the nucleic acid. These delivery systems are often therapeutically unacceptable due to toxicity or immune system reactivity.

Vaccines and therapies to prevent and treat Norovirus infections do not exist, despite the worldwide prevalence of Norovirus infections. Outbreaks of human gastroenteritis attributable to Norovirus commonly occur in group setting, such as hospitals, nursing homes, schools, dormitories, cruise ships and military barracks.

A novel strain in the rabies family of viruses, the Shimoni bat virus (SHIBV), has been discovered. Phylogenic and antigenic patterns identify SHIBV as a new species of Lyssavirus. Phylogenic reconstructions of SHIBV and monoclonal antibody typing were used to demonstrate a distinct genetic antigenic pattern. This unique genetic information may be used to create antigens or vaccines against SHIBV and provides opportunity for the development of new diagnostics, therapeutics, and prophylactic therapies for viral infection.