Interfacing artificial materials with biological tissues remains a challenge. The direct contact of their surface with the biological milieu results in multiscale interactions, in which biomacromolecules adsorb and act as transducers mediating the interactions with cells and tissues. So far, only antifouling polymer brushes have been able to conceal the surface of synthetic materials. However, their complex synthesis has precluded their translation to applications. Here, it is shown that ultrathin surface-attached hydrogel coatings of N-(2-hydroxypropyl) methacrylamide (HPMA) and carboxybetaine methacrylamide (CBMAA) provide the same level of protection as brushes. In spite of being readily applicable, these coatings prevent the fouling from whole blood plasma and provide a barrier to the adhesion of Gram positive and negative bacteria. The analysis of the components of the surface free energy and nanoindentation experiments reveals that the excellent antifouling properties stem from the strong surface hydrophilicity and the presence of a brush-like structure at the water interface. Moreover, these coatings can be functionalized to achieve antimicrobial activity while remaining stealth and non-cytotoxic to eukaryotic cells. Such level of performance is previously only achieved with brushes. Thus, it is anticipated that this readily applicable strategy is a promising route to enhance the biocompatibility of real biomedical devices.
Nature utilizes endothelium as a blood interface that perfectly controls hemostasis, preventing the uncontrolled formation of thrombi. The management of positive and negative feedback that finely tunes thrombosis and fibrinolysis is essential for human life, especially for patients who undergo extracorporeal circulation (ECC) after a severe respiratory or cardiac failure. The exposure of blood to a surface different from healthy endothelium inevitably initiates coagulation, drastically increasing the mortality rate by thromboembolic complications. In the present study, an ultrathin antifouling fibrinolytic coating capable of disintegrating thrombi in a self-regulated manner is reported. The coating system is composed of a polymer brush layer that can prevent any unspecific interaction with blood. The brushes are functionalized with a tissue plasminogen activator (tPA) to establish localized fibrinolysis that solely and exclusively is active when it is required. This interactive switching between the dormant and active state is realized through an amplification mechanism that increases (positive feedback) or restores (negative feedback) the activity of tPA depending on whether a thrombus is detected and captured or not. Thus, only a low surface density of tPA is necessary to lyse real thrombi. Our work demonstrates the first report of a coating that self-regulates its fibrinolytic activity depending on the conditions of blood.
The construction of biomembranes that faithfully capture the properties and dynamic functions of cell membranes remains a challenge in the development of synthetic cells and their application. Here a new concept for synthetic cell membranes based on the self‐assembly of amphiphilic comb polymers into vesicles, termed ionic combisomes (i‐combisomes) is introduced. These combs consist of a polyzwitterionic backbone to which hydrophobic tails are linked by electrostatic interactions. Using a range of microscopies and molecular simulations, the self‐assembly of a library of combs in water is screened. It is discovered that the hydrophobic tails form the membrane's core and force the backbone into a rod conformation with nematic‐like ordering confined to the interface with water. This particular organization resulted in membranes that combine the stability of classic polymersomes with the biomimetic thickness, flexibility, and lateral mobility of liposomes. Such unparalleled matching of biophysical properties and the ability to locally reconfigure the molecular topology of its constituents enable the harboring of functional components of natural membranes and fusion with living bacteria to “hijack” their periphery. This provides an almost inexhaustible palette to design the chemical and biological makeup of the i‐combisomes membrane resulting in a powerful platform for fundamental studies and technological applications.
Interfacing blood with any artificial surface instantly triggers the activation of coagulation at the interface, posing a risk of adverse thromboembolic complications. Immediately upon contact, blood proteins adsorb to the surface turning it into an active prothrombogenic and proinflammatory interface promoting the activation of platelets and the coagulation cascade. Here, an interactive hemocompatible nanocoating is designed that synergistically combines antifouling polymer brushes with the activity of an anti‐FXIIa antibody to tackle the two main causes of surface‐induced coagulation. The brushes provide a passive layer rendering the surface stealth and non‐thrombogenic against blood activation. Furthermore, as soon as traces of FXIIa arise, the coating immediately and specifically scavenges it, thus actively switching‐off contact activation right at the beginning. Moreover, a means is developed to translate this coating to a broad range of polymeric surfaces commonly used in medical devices. The coated surfaces prevent protein adsorption and provide a barrier to bacterial colonization while being capable of capturing biologically relevant concentrations of FXIIa. Notably, the coating completely prevents the formation of clots on the surface when exposed to blood. Thus, the interactive anti‐FXIIa nanocoating provides a new avenue to improve the hemocompatibility of medical devices in a safe and efficient manner.
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