Image created by Dr. Michael J. Miller
A new diagnostic method would confirm sepsis infections earlier, cutting critical hours in the "race against time" to save patients' lives.
Publishing in npj Digital Medicine, the team from KTH Royal Institute of Technology and Uppsala University say their diagnostic process offers a speedier alternative to the bacteria culturing process hospitals routinely use to identify suspected bloodstream infections.
The process uses a centrifuge to separate bacteria from blood cells, and automatic microscopy for detection, enabling a clinic to confirm bacterial infection in as little as two hours using software trained by artificial intelligence, says Henar Marino Miguelez, a doctoral student at KTH Royal Institute of Technology. She and doctoral student Mohammad Osaid were the study's lead authors.
By contrast, hospital labs generally need at least a day of incubation before the growth of infectious bacteria begins to reveal itself in blood cultures.
"Diagnosing sepsis is a race against time," Marino Miguelez says. "With every hour of delayed treatment of patients in septic shock, survival rates drop by 8%."
By enabling prompt identification of pathogens, the appropriate antibiotic treatment can be started sooner, says Wouter van der Wijngaart, a professor at KTH Royal Institute of Technology who leads research in microfluidic and biomedical systems.
Typically, a clinic will put a patient on a broad-spectrum antibiotic when sepsis is suspected, at least until they identify the pathogen. But that precaution carries its own risks, due to the inherent drug toxicity, attacking beneficial gut bacteria and promoting the emergence of antibiotic-resistant strains.
"It takes a hospital two to four days before they are sure which antibiotic to treat a bloodstream infection with," van der Wijngaart says. "We're trying to do this in four to six hours."
In tests using blood samples spiked with bacteria, the system successfully detected E. coli, K. pneumoniae, and E. faecalis at clinically relevant levels, as low as seven to 32 bacterial colony-forming units per milliliter of blood.
While the method proved to work well with these bacteria, it did not for staphylococcus aureus, which hides in blood clots. Miguelez says the researchers are working on ways to fix that.
The technique employs a "smart centrifugation," which spins blood samples on top of an agent that causes bacteria to float upwards while blood cells sediment downwards, leading to a clear, liquid layer containing bacteria but no blood cells. This liquid is then injected into a chip with microscale channels, where it flows easily.
Minuscule traps in the chip capture the separated bacteria, and any bacteria growth quickly becomes visible in automated time-lapse microscopy images analyzed by the machine learning software.
The work was a collaboration between the teams of van der Wijngaart at KTH, and Johan Elf and Carolina Wählby at Uppsala University.
Reference
M. Henar Marino Miguélez et al, Culture-free detection of bacteria from blood for rapid sepsis diagnosis, npj Digital Medicine (2025). DOI: 10.1038/s41746-025-01948-w
Abstract
Approximately 50 million people suffer from sepsis yearly, and 13 million die from it. For every hour a patient with septic shock is untreated, their survival rate decreases by 8%. Therefore, rapid detection and antibiotic susceptibility profiling of bacterial agents in the blood of sepsis patients are crucial for determining appropriate treatment. Here, we introduce a method to isolate bacteria from whole blood with high separation efficiency through Smart centrifugation, followed by microfluidic trapping and subsequent detection using deep learning applied to microscopy images. We detected, within 2 h, E. coli, K. pneumoniae, or E. faecalis from spiked samples of healthy human donor blood at clinically relevant concentrations as low as 9, 7 and 32 colony-forming units per ml of blood, respectively. However, the detection of S. aureus remains a challenge. This rapid isolation and detection represents a significant advancement towards culture-free detection of bloodstream infections.