From Flinders University 21/10/23

Researchers have used plasma technology to transform blue-green algae into a wound-healing coating. Credit: Getty

Researchers at Flinders University have taken a major step in the field of wound care by using plasma technology to ‘transform’ Spirulina microalgae into ultrathin bioactive coatings.

The innovative approach uses argon atmospheric plasma jet technology to transform Spirulina maxima, the blue-green microalgae, into bioactive coatings which can tackle bacterial infections while also promoting faster wound healing and applying potent anti-inflammatory properties.

“This holds promise, especially for the treatment of chronic wounds, which often pose challenges due to prolonged healing times,” says Dr Vi Khanh Truong, from the Flinders University Biomedical Engineering Laboratory.

Dr Vi Khanh Truong, right, with first author Ms Tuyet Pham, whose Master of Biotechnology thesis formed the basis of the study. Credit: Flinders University

“This novel approach could reduce the risk of toxic reactions to silver and other nanoparticles and rising antibiotic-resistance to common commercial coatings used in wound dressings.”

The latest development, published in the high-impact international peer-reviewed nanotechnology journal Small, reveals a new patented plasma-assisted technology which sustainably processes Spirulina maxima biomass into bioactive ultrathin coatings that can be applied to wound dressings and other medical devices which accelerate healing, modulate inflammation and even protect patients from infection.

The new technique could be readily applied to other types of natural supplements, adds Dr Truong.

A schematic depicting the one-step argon atmospheric pressure plasma jet (Ar-APJ) process to transform S. maxima biomass into an ultrathin bioactive coating. A) S. maxima is sprayed onto a universal substrate. B) Ar-APJ process transforms the S. maxima biomass into a durable, bioactive, ultrathin coating. C) Antibacterial wound dressings as a proposed application for the Ar-APJ technology. Credit: Small

“We are using the plasma coating technology to turn any type of biomass – in this case Spirulina maxima – into a more sustainable high-end coating.”

Extract of S. maxima is often used as a protein supplement and to treat skin disorders such as eczema, psoriasis and other conditions.

Researchers say the new plasma technology is the first of its kind and could be a “game-changer” for wound healing around the world.

The WHO has warned that antimicrobial resistance is one of the top public health threats facing humanity in the 21st century.

Overview of argon atmospheric plasma jet (Ar-APJ) system. A) Photograph showing the setup argon atmospheric plasma treatment (Ar-APJ) used to transform S. maxima biomass into a robust ultrathin coating. B) Photograph showing the argon atmospheric plasma jet (Ar-APJ). C) OES spectra of Ar-APJ at the argon flow rate of 10 LPM and voltage at 10 kV. D) Illustration of how Ar-APJ can turn S. maxima into a contiguous ultrathin coating. Credit: Small

Associated with the death of close to 5 million people in 2019, it is forecast to cost world economies upwards of US$1 trillion by 2050 if no action is taken.

Multiple genetic changes in common bacteria, such as Staphylococcus aureus and Pseudomonas aeruginosa, can lead them to become resistant to multiple antibiotics, forming ‘superbugs’.

Co-author of the new study, Matthew Flinders Professor Krasimir Vasilev, NHMRC Leadership Fellow, says the technology offers a better solution to current commercial applications, including gold and copper coatings, which will be an important tool to combat antibiotic resistance.

“This new plasma-facilitated downstream processing can improve extraction and purification of useful compounds from biomass without the need for harmful solvents and a lot of energy input,” says Professor Vasilev, Director of the Flinders Biomedical Nanoengineering Lab.

Morphological analysis of S. maxima following Ar-APJ treatment, observed using epifluorescence (left) and scanning electron microscopy (SEM) (right) imaging techniques. Morphology of A) untreated S. maxima. S. maxima treated with Ar-APJ for a duration of B) 100 s and C) 200 s over a surface area of 1 cm2, resulting in significant changes in the cell wall structure.  Credit: Small

“We are now seeking avenues for commercialisation of this unique technology.”

“Currently there are no commercial wound dressings that simultaneously fight and protect from infection, favourably modulate inflammation and stimulate healing.”

“We believe that the technology will offer a market advantage to medical wound dressing manufacturers and, by reaching the hospitals, make a difference to healthcare and patients.”

The Covid-19 pandemic increased the need for non-toxic, biocompatible, biostable antimicrobial coatings, a market projected to increase in value from almost US$4 billion to $6.8 billion within five years.

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