The Burden of Chronic Wounds: A Growing Health Crisis in Singapore

Chronic wounds, defined as injuries that fail to heal within three months despite standard care, pose a significant challenge worldwide and particularly in Singapore. These non-healing lesions include diabetic foot ulcers, pressure injuries, and venous leg ulcers, affecting vulnerable populations such as the elderly and those with diabetes. Globally, an estimated 18.6 million people develop diabetic foot ulcers annually, with up to one in three diabetics at lifetime risk, often leading to severe complications like lower-limb amputations. In Singapore, over 16,000 new cases emerge each year, driven by an aging population and diabetes prevalence nearing 15% among adults, nearly double the global average. The economic toll is staggering, accounting for roughly 0.07% of Singapore's GDP, or about S$350 million annually in direct healthcare costs, including hospitalizations and treatments.

Traditional management relies on debridement, antibiotics, and dressings, yet many wounds persist due to underlying infections by opportunistic pathogens. This persistent issue not only prolongs suffering but also strains healthcare resources, highlighting the urgent need for innovative therapies rooted in understanding bacterial-host interactions.

NTU Singapore Leads Breakthrough Discovery on Wound Healing Saboteurs

A team from Nanyang Technological University (NTU) Singapore, in collaboration with the University of Geneva, has unveiled why certain chronic wounds resist healing. Published in Science Advances on January 17, 2026 (DOI: 10.1126/sciadv.aeb5297), their study identifies Enterococcus faecalis (E. faecalis), a ubiquitous gut bacterium and opportunistic pathogen, as a key culprit. Led by NTU Associate Professor Guillaume Thibault from the School of Biological Sciences and Professor Kimberly Kline from the University of Geneva (SCELSE Visiting Professor at NTU), with first author NTU Research Fellow Dr. Aaron Ming Zhi Tan, the research shifts focus from bacterial killing to neutralizing their metabolic weapons.

"Our findings show that the bacteria’s metabolism itself is the weapon, which was a surprise finding previously unknown to scientists," said Assoc Prof Thibault. This NTU-led effort exemplifies Singapore's push in biomedical research, positioning institutions like NTU as hubs for tackling antimicrobial resistance.

Enterococcus faecalis: The Opportunistic Pathogen in Chronic Infections

Enterococcus faecalis, a Gram-positive bacterium commonly residing in the human gut, becomes problematic in wounds, especially diabetic foot ulcers where it forms biofilms. Unlike toxin-producing pathogens like Staphylococcus aureus, E. faecalis thrives via extracellular electron transport (EET), a respiratory chain exporting electrons outside the cell. This process generates superoxide, which spontaneously converts to hydrogen peroxide (H₂O₂), a reactive oxygen species (ROS).

• Prevalent in 30-50% of chronic wound infections globally.
• Often multi-drug resistant, complicating antibiotic therapy.
• Forms persistent biofilms evading immune clearance.

In Singapore's multi-ethnic population, E. faecalis infections exacerbate diabetic complications, with studies showing high incidence in tertiary care settings.

The Vicious Cycle: Hydrogen Peroxide, Oxidative Stress, and Cellular Paralysis

The NTU study elucidates a step-by-step sabotage: E. faecalis' EET floods the wound microenvironment with H₂O₂. This ROS induces oxidative stress in keratinocytes, the primary skin cells driving re-epithelialization.

1. H₂O₂ enters keratinocytes, causing protein misfolding.
2. Activates unfolded protein response (UPR) via IRE1 and PERK sensors in the endoplasmic reticulum.
3. UPR hyperactivation halts protein synthesis, impairs migration, and promotes inflammation over repair.
4. Results in stalled wound closure, even post-antibiotics.

Single-cell RNA sequencing from mouse wound models confirmed UPR enrichment in infected keratinocytes, with markers like XBP1s and CHOP upregulated. This metabolic virulence bypasses immune killing, explaining chronicity.

Why Antibiotics Alone Fail Against Persistent Wounds

Antibiotics target bacterial growth but leave residual H₂O₂, perpetuating stress. NTU experiments showed antibiotic-treated E. faecalis still induced UPR, unlike EET-deficient mutants (Δnadh or Δndh mutants) producing 50-70% less ROS and allowing full healing. In Singapore, where antibiotic resistance rates for Enterococcus exceed 40% in hospitals, this underscores the need for adjunct therapies.

Adj Assoc Prof Timothy Barkham from Tan Tock Seng Hospital noted: "Exploring alternative approaches beyond antibiotics is both timely and necessary."

Catalase: The Antioxidant Game-Changer for Wound Repair

Catalase, an enzyme decomposing H₂O₂ to water and oxygen, reversed damage. In vitro scratch assays, catalase-treated infected keratinocytes regained 80-90% migration speed, matching uninfected controls. Even antibiotic-resistant strains were neutralized without killing bacteria, preserving microbiome balance.

Prior research on catalase-mimicking nanozymes in dressings supports this; NTU's findings pave for clinical translation.ACS study on nanozyme dressings Future prototypes: Antioxidant-infused hydrogels or bandages for diabetic clinics.

Robust Evidence from NTU's Multifaceted Experiments

The study integrated:

IRE1 inhibitor (4μ8c) confirmed UPR's role in migration. These human-relevant models bridge lab to bedside.

Transforming Diabetic Foot Care in Singapore

Singapore reports 500-600 diabetic foot ulcer (DFU) cases yearly at major centers, with 37.9% five-year mortality. NTU's catalase pathway could slash amputations, aligning with Health Promotion Board's diabetes prevention. For researchers, this opens higher ed research jobs in antimicrobial alternatives at NTU's SCELSE.SCELSE overview

Global Impact and NTU's Research Ecosystem

Beyond Singapore, this addresses 25% of diabetes-related hospitalizations from infected DFUs. NTU's Lee Kong Chian School of Medicine and SCELSE foster interdisciplinary work; Prof Kline's expertise in Enterococcus biofilms complements Thibault's cellular stress lab. Related NTU efforts include wound patches with LKCMedicine.

Explore higher education news on Singapore's biomed advances or Singapore university jobs.

Path Forward: From Bench to Bedside Trials

Next: Animal models for catalase delivery, then Phase I trials. Nanozyme dressings with catalase-like activity show promise in preclinicals. Assoc Prof Thibault envisions: "Neutralise the actual cause – the reactive oxygen species." This could redefine wound care amid rising resistance.

For aspiring biomedics, NTU offers faculty positions and career advice.

Photo by Jayjayli on Unsplash

Career Opportunities in Wound Healing Research at Singapore Universities

NTU's breakthrough highlights demand for experts in microbiology, oxidative stress, and biomaterials. Check Rate My Professor for NTU faculty insights, higher ed jobs, university jobs, and higher ed career advice. Postdocs and lecturers in biomed thrive here amid Singapore's R&D investments.