Abstract
Hydrogels are finding increased clinical utility as advances continue to exploit their favorable material properties. Hydrogels can be adapted for many applications, including surface coatings and drug delivery. Anti-infectious surfaces and delivery systems that actively destroy invading organisms are alternative ways to exploit the favorable material properties offered by hydrogels. Sterilization techniques are commonly employed to ensure the materials are non-infectious upon placement, but sterilization is not absolute and infections are still expected. Natural, anti-bacterial proteins have been discovered which have the potential to act as anti-infectious agents; however, the proteins are toxic and need localized release to have therapeutic efficacy without toxicity. In these studies, we explore the use of the glutathione s-transferase (GST) to anchor the bactericidal peptide, melittin, to the surface of poly(ethylene glycol) diacrylate (PEGDA) hydrogel microspheres. We show that therapeutic levels of protein can be anchored to the surface of the microspheres using the GST anchor. We compared the therapeutic efficacy of recombinant melittin released from PEGDA microspheres to melittin. We found that, when released by an activating enzyme, thrombin, recombinant melittin efficiently inhibits growth of the pathogenic bacterium Streptococcus pyogenes as effectively as melittin created by solid phase peptide synthesis. We conclude that a GST protein anchor can be used to immobilize functional protein to PEGDA microspheres and the protein will remain immobilized under physiological conditions until the protein is enzymatically released.
Highlights
Most modern advances in medical technology put sterility as a first point in design principles
We concluded that the interaction between GSTGFP and poly(ethylene glycol) diacrylate (PEGDA)-GSH microspheres was occurring predominantly at surface of the microspheres
To further confirm the specificity of the interactions of glutathione s-transferase (GST)-green fluorescent protein (GFP) with the surface and to give a preliminary understanding of the expected response of the microspheres following injection into extracellular fluids, we examined the release of protein from microspheres in the presence of free GSH
Summary
Most modern advances in medical technology put sterility as a first point in design principles. These systems are passively sterilized to prevent infection before they are used. Materials implanted or inserted into the body are expected to have an incidence of infection with even the best methods of sterilization. Nosocomial infections from passively sterilized materials, e.g. catheters, artificial joints, pacemakers and drug pumps, cause more than 1.5 million deaths each year [1,2,3]. Active anti-infectious materials are thought to be superior to the currently used, passively sterilized, noninfectious materials in maintaining sterility in non-sterile environments
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