Novel
non-stick material joins portfolio
(BOSTON
"With widespread antibiotic resistance cropping up in many strains of infection–causing bacteria, developing out–of–the–box strategies to protect patients from bacterial biofilms has become a critical focus area for clinical researchers," said Wyss Institute Founding Director Donald Ingber, M.D., Ph.D., who is also the Judah Folkman Professor of Vascular Biology at Harvard Medical School and Boston Children's Hospital and Professor of Bioengineering at Harvard SEAS. "Liquid–infused polymers could be used to prevent biofilms from ever taking hold, potentially reducing rates of infection and therefore reducing dependence on antibiotic use."
Previously, Aizenberg and her team developed various other slippery surface technologies, including "SLIPS," the Slippery Liquid–Infused Porous Surfaces technology introduced in 2011 that can repel virtually any liquid or solid material and offer solutions to a wide range of applications.
SLIPS inspired the invention of a different type of slippery surface using tethered–liquid perfluorocarbons, known as TLP coating, developed in collaboration between Aizenberg and Ingber in 2014. TLP coating uses FDA–approved materials to prevent bacterial build–up and sepsis from occurring due to the use of medical implants or devices, while eliminating the need for conventional and side effect–prone anticoagulant drugs.
And the most recently developed approach could also have implications beyond the medical field. "We could apply liquid–infused polymers to other materials plagued with biofouling problems, such as waste–water management systems, maritime vessels or oil pipes," said one of the study's lead co–authors Philseok Kim, Ph.D., who was formerly a Senior Research Scientist at the Wyss Institute and is currently co–founder and Vice President of SLIPS Technologies, Inc.
Given the recent success of the experiment, Aizenberg and her team hope the newest technology will further strengthen the impact of the portfolio of slippery surface technologies. "Each technology in our portfolio has different properties and potential uses, but collectively this range of approaches to surface coatings can prevent a broad range of life–threatening problems, from ice accumulation on airplane wings to bacterial infections in the human body," said Aizenberg.
http://wyss.harvard.edu/viewpressrelease/190/
of slippery surface technologies
Infusing liquids into polymers makes long lasting,
self–replenishing material that repels deadly bacterial build-up (
The new
approach, which its inventors are calling "liquid–infused
polymers", joins an arsenal of slippery surface coatings that
have been developed at Harvard's Wyss Institute for Biologically Inspired
Engineering and School
of Engineering
The technology
leverages the molecular structure of polymers, which makes them highly capable
of taking up and storing considerable volumes of lubricating liquids in their
molecular structure, like sponges. This allows for absorption of a large
reservoir of lubricant, which can then travel to the surface and render it
continuously slippery and repellent — creating an environment that challenges bacteria's
ability to colonize. The team led by Joanna Aizenberg — Wyss Institute Core
Faculty member, the Amy Smith Berylson Professor of Materials Science at
Harvard SEAS, Professor of Chemistry and Chemical Biology in Harvard's Faculty
of Arts and Sciences, and Co–Director of the Kavli Institute for Bionano
Science and Technology — is designing various such liquid–infused polymer
systems.
For the current
study, they have chosen a solid silicone polymer, the same kind already used in
today's medical tubing, saturated with a liquid, silicone oil. Both components
are safe and non–toxic, and are already used in various medical devices and
common products like cosmetics.
"The solid
silicone tubing is saturated with silicone oil, soaking it up into all of the
tiny spaces in its molecular structure so that the two materials really become
completely integrated into one," said Caitlin Howell, Ph.D., a
Postdoctoral Researcher at the Wyss Institute and a co–author on the new
findings.
It's this
saturation process that makes the liquid–infused polymer so powerful and could
result in a material able to withstand conventional sterilization methods and
long–lasting use. This is due to the fact that the surface does not lose its
slipperiness over time — the silicone oil continuously diffuses to the surface,
replenishing itself to replace any oil that is pulled away by liquids flowing
against it, such as urine, blood, or gastro–intestinal fluids.
To test the
liquid–infused polymer's effectiveness in biofilm prevention, the study's lead
author Noah MacCallum, an exchange undergraduate student at SEAS, exposed
treated and untreated medical tubing to Pseudomonas aeruginosa, Escherichia
coli, and Staphylococcus epidermidis, which are common pathogenic
bacteria that form biofilms and are frequent culprits of urinary, tissue, and
blood infections. The experiment confirmed that the liquid–infused polymer
tubing greatly reduced bacterial adhesion and largely eliminated biofilm
formation.
As such, the
new approach could be leveraged to prevent bacterial infections associated with
the biofilm formation on catheters and other medical devices. This preventative
aspect is crucial given that once biofilms develop they are remarkably
resistant to removal, a problem that is compounded by rising antibiotic
resistance in bacteria."With widespread antibiotic resistance cropping up in many strains of infection–causing bacteria, developing out–of–the–box strategies to protect patients from bacterial biofilms has become a critical focus area for clinical researchers," said Wyss Institute Founding Director Donald Ingber, M.D., Ph.D., who is also the Judah Folkman Professor of Vascular Biology at Harvard Medical School and Boston Children's Hospital and Professor of Bioengineering at Harvard SEAS. "Liquid–infused polymers could be used to prevent biofilms from ever taking hold, potentially reducing rates of infection and therefore reducing dependence on antibiotic use."
Previously, Aizenberg and her team developed various other slippery surface technologies, including "SLIPS," the Slippery Liquid–Infused Porous Surfaces technology introduced in 2011 that can repel virtually any liquid or solid material and offer solutions to a wide range of applications.
SLIPS inspired the invention of a different type of slippery surface using tethered–liquid perfluorocarbons, known as TLP coating, developed in collaboration between Aizenberg and Ingber in 2014. TLP coating uses FDA–approved materials to prevent bacterial build–up and sepsis from occurring due to the use of medical implants or devices, while eliminating the need for conventional and side effect–prone anticoagulant drugs.
And the most recently developed approach could also have implications beyond the medical field. "We could apply liquid–infused polymers to other materials plagued with biofouling problems, such as waste–water management systems, maritime vessels or oil pipes," said one of the study's lead co–authors Philseok Kim, Ph.D., who was formerly a Senior Research Scientist at the Wyss Institute and is currently co–founder and Vice President of SLIPS Technologies, Inc.
Given the recent success of the experiment, Aizenberg and her team hope the newest technology will further strengthen the impact of the portfolio of slippery surface technologies. "Each technology in our portfolio has different properties and potential uses, but collectively this range of approaches to surface coatings can prevent a broad range of life–threatening problems, from ice accumulation on airplane wings to bacterial infections in the human body," said Aizenberg.
http://wyss.harvard.edu/viewpressrelease/190/
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