Polymers Are Tough on Microbes, Soft on Skin

Polymers that kill germs rapidly and effectively will help in the fight against multidrug-resistant microbes

RNA molecules, polymers, antimicrobial resistance, Aging White Blood Cells, microviscosity, Transplant Drug, Nanophotonics, photonics, Built-In Nanobulbs, cerebral cortex, cancer cells, nanowires, optoelectronic, solar energy, gold nanowires, Chikungunya virus, concrete, glaucoma, light-emitting diode, Proteomics, nanostructures, nickel catalyst, Ultrafast lasers, liver capsular macrophages, obesity, cancer, lignin polymer, liver capsular macrophages, Ultrafast lasers, monocyte cells, cancer treatments, antibody drug, gene mutations, quantum-entangled photons, gut microbes, skin aging, stroke, machine learning, Cloned tumors, cancer, Rare Skin Disease, terahertz lasers, silicon-nanostructure pixels, oral cancer, heart muscle cells, cancer, cancer stem cells, gastric cancer, microelectromechanical systems, data storage, silicon nanostructures, Drug delivery, cancer, muscle nuclei, Lithography, silicon nanostructures, Quantum matter, robust lattice structures, potassium ions, Photothermal therapy, Photonic devices, Optical Components, retina, allergy, immune cells, catalyst, Nanopositioning devices, mold templates, lung cancer, cytoskeletons, hepatitis b, cardiovascular disease, memory deficits, Photonics, pre-eclampsia treatment, hair loss, nanoparticles, mobile security, Fluid dynamics, MXene, Metal-assisted chemical etching, nanomedicine, Colorectal cancer, cancer therapy, liver inflammation, cancer treatment, Semiconductor lasers, zika virus, catalysts, stem cells, fetal immune system, genetic disease, liver cancer, cancer, liver cancer, RNA editing, obesity, Microcapsules, genetic disease, Piezoelectrics, cancer, magnesium alloy, Quantum materials, therapeutic antibodies, diabetes, 2D materials, lithium-ion batteries, obesity, lupus, surfactants, Sterilization, skin on chip, Magnetic Skyrmions, cyber-security, wound infections, human genetics, immune system, eczema, solar cells, Antimicrobials, joint disorder, genetics, cancer

Inexpensive antimicrobial polymers that are gentle on the skin and highly effective in killing microbes have been developed by A*STAR researchers1. They have promise for use in surgical scrubs and disinfectants.

Most antibiotics work by disrupting the specific biochemical pathways microbes use to make the proteins and enzymes which are essential for their survival. This strategy makes them lethal to microbes but safe to the cells of humans and other mammals. However, it is easy for microbes to develop resistance to such antibiotics, which has led to the widespread problem of multi drug-resistant microbes.

The antimicrobial compounds of the body’s immune system use a different tactic — they fight microbes by destroying their membranes. Since this approach is based on the inherent electrical properties of the cell membrane, it is much harder, if not impossible, for microbes to develop resistance.

Now, Yi Yan Yang of the A*STAR Institute of Bioengineering and Nanotechnology and her co-workers, in collaboration with IBM Almaden Research Center, have developed powerful antimicrobial polymers that employ the same strategy. The polymers with optimized structures killed almost 100 per cent of microbes within two minutes. They were also softer on the skin of mice than commercial surgical scrubs that are currently used in clinical settings.

“Our polymers kill a broad spectrum of microbes, especially the difficult-to-kill Pseudomonas aeruginosa, faster than any of the many antimicrobial peptides and polymers reported to date,” comments Yang. “With their superfast bactericidal effect and skin compatibility, these polymers are promising candidates for use as surgical scrubs, hand washes and disinfectants,” she adds.

The polymers have two key components: positive charges and hydrophobic parts. Their positively charged components interact with the negatively charged membranes of pathogenic microbes, while the hydrophobic parts of the polymers enter the two layers of fat cells inside membranes. This double action ruptures the membrane and destroys the microbe. Since the surfaces of mammalian cells are less negatively charged than those of microbes, cells such as red blood cells are immune to the polymers’ action.

The researchers found that repeated use of the polymer at sub-lethal doses did not lead to bacterial resistance. In addition, the polymers are inexpensive to make and can be synthesized from commercially available starting materials.

“Building on this work, we are developing biodegradable versions of the polymers,” says Yang. “They are designed to degrade into benign, environmentally-friendly compounds. Such biodegradable antimicrobial polymers may be used as preservatives in cosmetics and even food products.”

The A*STAR-affiliated researchers contributing to this research are from the Institute of Bioengineering and Nanotechnology.

Source : A*STAR Research