In the fight against superbugs, scientists have discovered a class of agents that can make some of the most notorious strains vulnerable to the same antibiotics that they once handily shrugged off. The report on the promising agents called metallopolymers appears in the Journal of the American Chemical Society.
Chuanbing Tang and colleagues note that the antibiotic-resistant bacteria methicillin-resistant Staphylococcus aureus (MRSA) is responsible for a significant fraction of the infections that patients acquire in hospitals. According to the Centers for Disease Control and Prevention (CDC), MRSA usually spreads in hospitals when a health care provider with contaminated hands unknowingly passes it along to a patient. It can cause serious problems such as pneumonia, and can lead to death. One of the ways MRSA undermines conventional treatments is by producing enzymes that inactivate traditional antibiotics such as penicillin. Scientists have been developing new agents to combat these enzymes, but the agents so far have fallen short. Tang's team wanted to find a better alternative.
They tested a recently discovered class of metallopolymers - large, metal-containing molecules - against several strains of MRSA. When paired with the same antibiotics MRSA normally dispatches with ease, the polymer/antibiotic combo evaded the bacteria's defensive enzymes and destroyed its protective walls, causing the bacteria to burst. Also, the metallopolymers mostly left red blood cells alone, which suggests they might have minimal side effects.
"These discoveries could pave a new platform to design antibiotics and antimicrobial agents to battle multidrug-resistant bacteria and superbugs," the researchers state.
The authors acknowledge funding from the National Science Foundation.
Soource: American Chemical Society
Our Understanding of Immune Issues Is Evolving: Here Are 5 Reasons Why
October 25th 2024The past 5 years in medicine have seen significant advances in RNA vaccines, understanding immune dysregulation, and improved interspecialty communication, promising better disease eradication and tailored treatments.