A team of chemists from the University of Warwick and Monash University has identified a promising, potent new antibiotic that seems to be much more effective than existing drugs against deadly superbugs like MRSA and shows no signs of resistance so far, encouraging news as the global threat of antimicrobial resistance continues to grow and the pipeline of new antibiotics continues to fall short. The molecule had been overlooked for decades as an intermediate chemical in the natural process to produce another known antibiotic, methylenomycin A, which was discovered 50 years ago, and despite having been synthesized multiple times, the synthetic intermediates have seemingly not been tested before for antimicrobial activity. The new antibiotic is much more potent than methylenomycin A itself—100 times more active against a range of serious bacteria. It could not only be a powerful new tool against rising drug resistance, but this work could also pave the way for new approaches to antibiotic discovery.
A team of researchers has developed an antivenom using antibodies from a llama and an alpaca that can neutralize venom from some of the world’s most venomous snakes. Snakebites are a neglected public health issue that kill around 20,000 people in sub-Saharan Africa yearly. Current antivenom treatments are usually specific to a single snake species, and it can be difficult to identify which of the many types of venomous snakes is behind a bite, making timely, effective treatment difficult to achieve. The researchers exposed an alpaca and a llama to venoms from 18 of the most dangerous snake species in sub-Saharan Africa, isolated the antibodies that the animals produced against the venom, and then combined some of those antibodies in a single cocktail. In mice, the treatment protected against toxins from 17 African snake species and reduced skin damage. Many scientists previously thought that developing a broad-spectrum antivenom would require too many antibodies to be practical because some venom can contain up to 100 toxins, but this study shows that a combination of just a handful of antibodies can neutralize the venom of many snake species, paving the way for the development of similar broad-spectrum antivenoms for other areas where snakebites are a common public health challenge.
Last week, Cepheid announced that its Xpert MTB/XDR test for tuberculosis (TB) drug resistance has been prequalified by the World Health Organization (WHO), enabling procurement through international agencies and greater access in areas with a high TB burden. The test is designed to detect resistance to multiple first- and second-line TB drugs from patient samples. It also delivers results quickly, within 90 minutes, allowing health care providers to make quicker, more reliable treatment decisions and have a better understanding of drug resistance, especially in regions with a high TB burden where timing and accuracy are critically important.