TY - JOUR
T1 - Study of the structure of hyperbranched polyglycerol coatings and their antibiofouling and anti-thrombotic applications
AU - Moore, Eli
AU - Robson, Alexander J.
AU - Crisp, Amy R.
AU - Cockshell, Michaelia P.
AU - Burzava, Anouck L. S.
AU - Ganesan, Raja
AU - Robinson, Nirmal
AU - Al-Bataineh, Sameer
AU - Nankivell, Victoria
AU - Sandeman, Lauren
AU - Tondl, Markus
AU - Benveniste, Glen
AU - Finnie, John W.
AU - Psaltis, Peter J,
AU - Martocq, Laurine
AU - Quadrelli, Alessio
AU - Jarvis, Samuel P.
AU - Williams, Craig
AU - Ramage, Gordon
AU - Rehman, Ihtesham U.
AU - Bursill, Christina A.
AU - Simula, Tony
AU - Voelcker, Nicolas H.
AU - Griesser, Hans J.
AU - Short, Robert D.
AU - Bonder, Claudine S.
PY - 2024/6/24
Y1 - 2024/6/24
N2 - While blood-contacting materials are widely deployed in medicine in vascular stents, catheters, and cannulas, devices fail in situ because of thrombosis and restenosis. Furthermore, microbial attachment and biofilm formation is not an uncommon problem for medical devices. Even incremental improvements in hemocompatible materials can provide significant benefits for patients in terms of safety and patency as well as substantial cost savings. Herein, a novel but simple strategy is described for coating a range of medical materials, that can be applied to objects of complex geometry, involving plasma-grafting of an ultrathin hyperbranched polyglycerol coating (HPG). Plasma activation creates highly reactive surface oxygen moieties that readily react with glycidol. Irrespective of the substrate, coatings are uniform and pinhole free, comprising O─C─O repeats, with HPG chains packing in a fashion that holds reversibly binding proteins at the coating surface. In vitro assays with planar test samples show that HPG prevents platelet adhesion and activation, as well as reducing (>3 log) bacterial attachment and preventing biofilm formation. Ex vivo and preclinical studies show that HPG-coated nitinol stents do not elicit thrombosis or restenosis, nor complement or neutrophil activation. Subcutaneous implantation of HPG coated disks under the skin of mice shows no evidence of toxicity nor inflammation.
AB - While blood-contacting materials are widely deployed in medicine in vascular stents, catheters, and cannulas, devices fail in situ because of thrombosis and restenosis. Furthermore, microbial attachment and biofilm formation is not an uncommon problem for medical devices. Even incremental improvements in hemocompatible materials can provide significant benefits for patients in terms of safety and patency as well as substantial cost savings. Herein, a novel but simple strategy is described for coating a range of medical materials, that can be applied to objects of complex geometry, involving plasma-grafting of an ultrathin hyperbranched polyglycerol coating (HPG). Plasma activation creates highly reactive surface oxygen moieties that readily react with glycidol. Irrespective of the substrate, coatings are uniform and pinhole free, comprising O─C─O repeats, with HPG chains packing in a fashion that holds reversibly binding proteins at the coating surface. In vitro assays with planar test samples show that HPG prevents platelet adhesion and activation, as well as reducing (>3 log) bacterial attachment and preventing biofilm formation. Ex vivo and preclinical studies show that HPG-coated nitinol stents do not elicit thrombosis or restenosis, nor complement or neutrophil activation. Subcutaneous implantation of HPG coated disks under the skin of mice shows no evidence of toxicity nor inflammation.
KW - non‐fouling
KW - biofilm
KW - X‐ray photoelectron spectroscopy
KW - thrombosis
KW - peripheral arterial disease
KW - in‐stent restenosis
KW - hyperbranched polyglycerol
U2 - 10.1002/adhm.202401545
DO - 10.1002/adhm.202401545
M3 - Article
SN - 2192-2640
JO - Advanced Healthcare Materials
JF - Advanced Healthcare Materials
M1 - 2401545
ER -