Healthcare uniforms laundered in domestic washing machines may be undermining efforts to control the spread of antibiotic-resistant bacteria in clinical settings, according to groundbreaking new research led by Katie Laird at De Montfort University. Published on April 30, 2025, in the open-access journal PLOS One, this study challenges the widely held assumption that home washing machines provide sufficient decontamination of healthcare textiles, highlighting a hidden vector in the escalating public health crisis of antimicrobial resistance.
Hospital-acquired infections (HAIs) remain a formidable challenge worldwide, with a significant percentage involving multidrug-resistant organisms. Healthcare workers’ uniforms, worn daily in high-risk environments, are often considered potential reservoirs for pathogenic bacteria. While institutional laundering services typically employ industrial-grade machines with stringent disinfection protocols, many healthcare professionals rely on domestic washers at home for their uniforms. The efficiency of these commonplace machines in eliminating dangerous microbes from heavily contaminated textiles had never before been systematically analyzed—until now.
Laird and her colleagues undertook an exhaustive evaluation of six widely-used domestic washing machine models, testing their disinfection efficacy under typical usage scenarios. The researchers contaminated fabric swatches, replicating bacterial loads found on healthcare workers’ uniforms, then subjected these swatches to hot water cycles adapted from rapid and normal domestic wash programs. The results were concerning: half of the machines failed to eliminate bacterial contamination during rapid cycles, and an alarming one-third were ineffective even during standard wash cycles, revealing a significant vulnerability in infection control protocols.
The study delved deeper by analyzing biofilms nestled inside the internal components of 12 domestic washing machines. Biofilms—complex microbial communities adhered to surfaces—are notoriously difficult to eradicate and can harbor antibiotic-resistant bacteria. Through DNA sequencing technologies, the team uncovered the presence of potentially pathogenic bacteria within these biofilms, alongside a troubling array of antibiotic resistance genes. This finding suggests that home machines can serve not only as ineffective decontamination tools but also as breeding grounds for resistant pathogens.
Further laboratory experiments illuminated the adaptive capabilities of bacteria exposed to domestic detergents. The bacteria demonstrated an unsettling ability to develop elevated resistance to these detergents, a phenomenon that concomitantly increased their resistance to certain clinically important antibiotics. This cross-resistance mechanism underscores the evolutionary pressure domestic laundering practices may inadvertently exert on microbial populations, compounding the risk of antibiotic resistance proliferation in hospital environments.
The implications of these findings are profound. Current laundering guidelines for healthcare workers, often centered on convenience and practicality, may be insufficient to prevent bacterial transmission via contaminated textiles. The research forces a reevaluation of the reliance on home laundering for healthcare uniforms and suggests that on-site laundering using industrial machines with validated disinfection standards could be a superior strategy to curb infection spread and antimicrobial resistance emergence.
Importantly, the survival and potential amplification of antibiotic-resistant bacteria within domestic machines reveal a vector that has been overlooked. Textile handling, washing temperature, detergent formulation, and wash cycle duration all influence microbial survival rates. Domestic washing machines lack the capacity to consistently meet the high temperature thresholds or prolonged disinfection times necessary to ensure uniform sterilization, unlike their industrial counterparts used in healthcare facilities.
The study’s authors emphasize that the persistence of resistant bacteria on healthcare textiles could facilitate indirect transmission pathways within hospitals, where vulnerable patient populations might be exposed. The intimate contact healthcare workers have with patients—including touch and proximity—could serve as conduits for pathogen transfer, undermining infection control measures like hand hygiene and environmental cleaning.
These results also raise questions about the design and maintenance of domestic washing machines. Accumulated biofilms within machines can serve as continuous sources of bacterial contamination and cross-infection. Routine cleaning and disinfection of machines, the use of higher temperature cycles, and possibly new detergent formulations might be necessary to mitigate these risks. However, the study highlights that even such measures may not fully address the problem posed by the innate limitations of domestic laundering systems.
Given the burgeoning threat of antimicrobial resistance to global health, the study advocates for urgent revision of laundering protocols and policies regarding healthcare textiles. This includes considering the infrastructure investment needed to ensure all healthcare uniforms are laundered in controlled, industrial environments specifically designed to neutralize resistant microorganisms. Such strategies would integrate with broader infection prevention frameworks, strengthening the resilience of healthcare facilities against resistant infections.
In their concluding remarks, the research team poignantly notes that tackling the transmission of infectious diseases requires scrutinizing every potential avenue—including the seemingly mundane task of laundering. Failure to address this vector could perpetuate a cycle of infection and resistance that challenges even the most robust antimicrobial stewardship initiatives. Reevaluating laundry practices, therefore, becomes as essential as hand hygiene or antibiotic prescribing reforms in the modern hospital setting.
This study represents a clarion call to healthcare systems worldwide, signaling the need for multidisciplinary approaches integrating microbiology, public health, engineering, and policy to confront the silent but dangerous risks posed by domestic laundering. The intersection of microbial ecology and everyday practices, such as how healthcare workers clean their uniforms, has significant ramifications extending beyond the washer, into the heart of clinical infection control.
By exposing the unforeseen hazards lurking within domestic washing cycles, Laird and her team compel a shift in perspective about infection control, emphasizing a holistic view that addresses all facets of microbial transmission. As hospitals grapple with rising antimicrobial resistance, the laundering of healthcare textiles emerges not just as a logistical concern but as a critical battlefield in the fight to preserve effective therapies and protect patient health.
Subject of Research: People
Article Title: Domestic laundering of healthcare textiles: Disinfection efficacy and risks of antibiotic resistance transmission
News Publication Date: April 30, 2025
Web References: http://dx.doi.org/10.1371/journal.pone.0321467
References: Cayrou C, Silver K, Owen L, Dunlop J, Laird K (2025) Domestic laundering of healthcare textiles: Disinfection efficacy and risks of antibiotic resistance transmission. PLoS ONE 20(4): e0321467.
Image Credits: Dr. Caroline Cayrou, CC-BY 4.0
Keywords: antimicrobial resistance, healthcare textiles, domestic laundering, washing machines, antibiotic-resistant bacteria, hospital-acquired infections, biofilms, microbial contamination, infection control, industrial laundering
Tags: antibiotic-resistant bacteria controlantimicrobial resistance in textilesdisinfection protocols for healthcaredomestic vs industrial washing machineseffectiveness of domestic washershealthcare uniforms launderinghome washing machineshospital-acquired infections preventionpathogenic bacteria in healthcarepublic health and textilesresearch on laundering efficacytextile decontamination methods