A collaborative team led by researchers from Great Ormond Street Institute of Child Health (GOSH), London and including researchers from the Wyss Institute for Biologically Inspired Engineering at Harvard University and BOA Biomedical in Cambridge has re-engineered the process of microbial pathogen identification in blood samples from pediatric sepsis patients using the Wyss Institute’s FcMBL broad-spectrum pathogen capture technology. The advance enables accurate pathogen detection with a combination of unprecedented sensitivity and speed, and could significantly improve clinical outcomes for pediatric and older patients with bloodstream infections (BSIs) and sepsis. The findings were published in PLoS ONE.
BSIs with various microbial pathogens can rapidly escalate to life-threatening sepsis when the body is overwhelmed by the multiplying invaders and shuts down its organs’ functions. In 2017, there were 48.9 million cases and 11 million sepsis-related deaths worldwide. Importantly, almost half of all global sepsis cases occurred among children, with an estimated 20 million cases and 2.9 million global deaths in those under five years of age.
To prevent BSIs from progressing to full-blown sepsis, the infection-causing bacterial or fungal species must be identified as fast as possible. Only then can optimal pathogen-tailored antibacterial or antifungal treatments be applied in time. The conventional method used in clinical laboratories to identify the causative pathogenic species is long and laborious, requiring two time-consuming culture steps that take at least 1 to 3 days to complete.
“For all patients with sepsis, their chances of surviving dramatically shrink the longer it takes to identify the infection-causing pathogen(s) and thus, receive the most promising antimicrobial treatment,” said Nigel Klein, M.D., Ph.D., pls, a Professor of Infectious Disease and Immunology at GOSH, and a senior author on the study. “At Great Ormond Street Hospital we have been working to demonstrate both the importance rapid diagnosis and the fact that with innovative approaches we can identify the causative organism in between 40 minutes and six hours. Compared to adult patients, sepsis in infants and small children progresses much faster, and therefore there is a real need for diagnostic methods that support early detection. Accurate diagnosis is even more significant due to the availability of only small blood volumes from paediatric patients which can make re-sampling challenging.”
In 2020, senior authors Klein and Elaine Cloutman-Green, Ph.D., a Consultant Clinical Scientist and Infection Control Doctor at GOSH, began collaborating with Lead Staff Scientist Michael Super, Ph.D. and Founding Director Donald Ingber, M.D., Ph.D. at Harvard’s Wyss Institute to solve this problem. “Based on our earlier success with FcMBL in isolating pathogens from joints as well as bovine and human blood with extraordinary efficiencies, we hypothesized that building an FcMBL-mediated pathogen capture into a modified clinical blood culture protocol could shorten the time and reduce the size of the required patient samples to yield the same results that time-consuming blood culture protocols provide,” said Super.
In the pathogen identification process currently performed in clinical settings, first, blood samples are added to bottles containing liquid media in which infectious microbes, if present, are amplified to a certain density. Then, the amplified microbes are grown on solid media as isolated colonies whose constituent cells eventually can be identified with a highly sensitive, yet fast and relatively inexpensive analytical method know as MALDI-TOF mass spectrometry (MS). “Indeed, isolating the infectious microbes directly from grown liquid blood cultures using FcMBL makes them available for MALDI-TOF MS analysis much earlier,” added Super.
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