Paper-based blood test developed by SMART researchers can rapidly determine the presence of SARS-CoV-2 neutralizing antibodies.
The Raman spectroscopy-based method enables early detection and quantification of pathogens in plants, to enhance plant disease management.
SMART researchers have developed an innovative method to detect and quantify the B.1.1.7 (Alpha) variant of concern via wastewater epidemiology.
SMART researchers combine rifaximin and clarithromycin to effectively restore the latter drug's efficacy.
Developed at SMART, the therapy stimulates the host immune system to more effectively clear bacterial infections and accelerate infected wound healing.
SMART researchers find explanation for why some patients might experience diarrhea after taking amoxicillin-clavulanate.
Rapid and accurate analytical test method enhances the production of high-quality cell therapy products.
An anomaly-detection model developed by SMART utilizes machine learning to quickly detect microbial contamination.
Developed at SMART, the nondestructive nanosensors could have wide applications in agricultural science.
Developed at SMART, the device can deliver controlled amounts of agrochemicals to specific plant tissues for research and could one day be used to improve crop quality and disease management.
Developed at SMART, the therapy stimulates the host immune system to more effectively clear bacterial infections and accelerate infected wound healing.
SMART breakthrough could help develop technologies that can identify materials according to desired properties for specific applications.
An anomaly-detection model developed by SMART utilizes machine learning to quickly detect microbial contamination.