Zwitterionic Polysulfobetaine Coating and Antiplatelet Liposomes Reduce Fouling in Artificial Lung Circuits

Abstract: The artificial lung has provided life‐saving support for pulmonary disease patients and recently afforded patients with severe cases of COVID‐19 better prognostic outcomes. While it addresses a critical medical need, reducing the risk of clotting inside the device remains challenging. Herein, a two‐step surface coating process of the lung circuit using Zwitterionic polysulfobetaine methacrylate is evaluated for its nonspecific protein antifouling activity. It is hypothesized that similarly applied coatings on … Show more

“…Cook K et al, [14][15][16] also recently developed several coating methods using 3,4-dihydroxyphenylalanine primer or a grafting-copolymerization technique with CB or SB polymer coating. While the polymeric or combination coatings showed significant reduction of thrombotic deposition, hurdles still remain regarding the feasibility of application to a commercial ECMO device due to the multi-step process.…”

“…While a PC polymer coating is already commercially available on an ECMO device (e.g., EUROSETS™), 11–13 degradation of the gas exchange performance and coating stability/durability for a long‐term period (over 1 month for an AAL) are still of concern. Cook K et al, 14–16 also recently developed several coating methods using 3,4‐dihydroxyphenylalanine primer or a grafting‐copolymerization technique with CB or SB polymer coating. While the polymeric or combination coatings showed significant reduction of thrombotic deposition, hurdles still remain regarding the feasibility of application to a commercial ECMO device due to the multi‐step process.…”

Epoxy silane sulfobetaine block copolymers for simple, aqueous thromboresistant coating on ambulatory assist lung devices

“…Cook K et al, [14][15][16] also recently developed several coating methods using 3,4-dihydroxyphenylalanine primer or a grafting-copolymerization technique with CB or SB polymer coating. While the polymeric or combination coatings showed significant reduction of thrombotic deposition, hurdles still remain regarding the feasibility of application to a commercial ECMO device due to the multi-step process.…”

“…While a PC polymer coating is already commercially available on an ECMO device (e.g., EUROSETS™), 11–13 degradation of the gas exchange performance and coating stability/durability for a long‐term period (over 1 month for an AAL) are still of concern. Cook K et al, 14–16 also recently developed several coating methods using 3,4‐dihydroxyphenylalanine primer or a grafting‐copolymerization technique with CB or SB polymer coating. While the polymeric or combination coatings showed significant reduction of thrombotic deposition, hurdles still remain regarding the feasibility of application to a commercial ECMO device due to the multi‐step process.…”

Epoxy silane sulfobetaine block copolymers for simple, aqueous thromboresistant coating on ambulatory assist lung devices

“…Also, highly negatively or positively charged latex particles enable thrombogenesis while hydrophilic, low-charged particles suppress thrombogenesis in platelet-rich plasma, , highlighting the need to balance ionic and hydrophobic interactions. For simplicity, however, a design principle is to use hydrophilic biomaterials such as poly(ethylene glycol) and poly(sulfobetaine) or superhydrophobic ones such as polysiloxane- and perfluorocarbon-based biomaterials to mitigate FBR. − Mechanistically, in hydrophilic biomaterials, a tightly bound hydrated layer can effectively impede protein adsorption and interaction with immune cells. At the same time, superhydrophobicity can successfully repel blood components, attenuating the adsorption of blood proteins.…”

Design Principles for Immunomodulatory Biomaterials

PDMS-based artificial lung membranes with enhanced permeation to overcome the bottleneck in CO2/O2 selectivity