Microscope image showing C difficile on hospital gown fibres before (left) and after (right) disinfectant treatment 

Microscope image showing C difficile on hospital gown fibres before (left) and after (right) disinfectant treatment 

New research has shown how surgical gowns used in hospitals are retaining superbug Clostridium difficile (C difficile), even after being treated with the recommended amount of disinfectant. 

The research, led by the University of Plymouth, tested single-use hospital surgical gowns (made of polypropylene) that had been infected with three different strains of C difficile, a bacteria that can cause severe diarrhoea, bowel complications and even death. 

Why the study took place 

After treating infected items for ten minutes with disinfectant containing 1,000 parts per million of chlorine – the amount and time recommended by the Department of Health and Social Care– the team found that all strains of C difficile spores still survived on the gowns and did not reduce, allowing them to potentially transfer to other items. 

The work was published today (Friday 12 July) in the journal Applied and Environmental Microbiology, with collaboration from Cardiff University, and supported by the Society for Applied Microbiology. 

The research took place because the gowns were suspected to be contributing to C difficile transmission in a USA hospital. Contaminated gowns from the USA hospital were tested for presence of C difficile and a deadly 027 type strain was isolated, showing that the gowns can pick up and retain the spores. 

What the study involved, and what the science shows

In this study, new gowns had the bacteria ‘spiked’ onto them for testing purposes.

Three strains of C difficile were tested including R20291, which caused severe outbreaks in UK hospitals between 2003 and 2006. This strain is known to cause mortality in patients as it is becoming resistant to the main antibiotic treatments, vancomycin and metronidazole.

To examine the ability of C difficile to adhere to, and subsequently transfer from, hospital surgical gowns, spores were applied directly to the surgical gowns in water for 10 seconds, 30 seconds, 1 minute, 5 minutes and 10 minutes before being removed and discarded. This was designed to mimic transfer of infectious bodily fluids in the clinical setting and assess the potential for onward transmission to patients. 

There was no significant difference between the amount of spores recovered from the gowns and the contact time of the spores to the gowns; suggesting that the spore transfer between surfaces occurred within the first 10 seconds of contact.

The items were then treated with 1,000 ppm chlorine-releasing disinfectant, sodium dichloroisocyanurate (NaDCC) to try and tackle the bug. 

Principal investigator and study lead Dr Tina Joshi, part of the Institute of Translational and Stratified Medicine (ITSMed) at the University of Plymouth, explains that this work can be applied to hospitals anywhere in the world, and should help inform future guidelines on infection control and biocides (bacteria killers). She said: 

“C difficile is a really nasty superbug and it’s so important that hospitals stop it from spreading. This study shows that even when we think an item has been suitably cleaned, it hasn’t been necessarily – 1,000 parts per million of chlorine just isn’t enough as the bacteria survived and grew after disinfection. 

"As well as possibly upping the concentration of the biocide, the research highlights the need for appropriate hygiene practices. Gowns should not be worn outside of isolated areas as our work has shown that C difficile spores are good at sticking to clinical surfaces, and can so easily be transferred, causing infections in patients. In an age where infections are becoming resistant to antibiotics, it’s worrying to think that other bacteria are becoming resistant to biocides. So the best thing we can do is ensure that infection control procedures are robust and standardised.” 

Dr Joshi is currently in Chile to further investigate the mechanisms behind the biocide resistance. 

In addition, she works on antimicrobial resistance, and is currently developing a new point-of-care test to detect antimicrobial resistant (AMR) genes in pathogens, all within the time frame of a doctor’s appointment. 

The full paper is entitled Biocide resistance and transmission of Clostridium difficile spores spiked onto clinical surfaces from an American healthcare facility and is available to view now in the journal Applied and Environmental Microbiology (doi 10.1128/AEM.01090-19). 

Plymouth Institute of Health and Care Research

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