Adhesive Coacervates Driven by Hydrogen‐Bonding Interaction

Abstract: Coacervate is the concentrated polymer-rich liquid phase that originates from the spontaneous liquid-liquid phase separation of a colloidal system, which has been considered as "the origin of life" for its high resemblance with protoplasm, [1] precellular systems, [2] and membrane-free organelles. [3] Coacervation also plays a critical role in constructing biological tissues (e.g., forming extracellular matrices via assembling elastin with tropoelastin) [4] and developing gradient properties in materials (e.g.… Show more

“…As a result, the solution became turbid and after centrifugation a viscous SUP‐surfactant complex was obtained. This liquid‐liquid phase separation behavior leads to the formation of protein‐surfactant coacervates [25, 26] . The water content was ≈30 % (w/w) in the SUP‐surfactant complexes as determined by thermogravimetric analysis (TGA) (Figure S3).…”

“…This liquid‐liquid phase separation behavior leads to the formation of protein‐surfactant coacervates. [ 25 , 26 ] The water content was ≈30 % (w/w) in the SUP‐surfactant complexes as determined by thermogravimetric analysis (TGA) (Figure S3). After lyophilizing for ≈30 min, ≈14 % of water remained in the coacervate (Figure S4), resulting in the formation of the protein‐based adhesive (Figure 1 C ).…”

Genetically Engineered Polypeptide Adhesive Coacervates for Surgical Applications

“…As a result, the solution became turbid and after centrifugation a viscous SUP‐surfactant complex was obtained. This liquid‐liquid phase separation behavior leads to the formation of protein‐surfactant coacervates [25, 26] . The water content was ≈30 % (w/w) in the SUP‐surfactant complexes as determined by thermogravimetric analysis (TGA) (Figure S3).…”

“…This liquid‐liquid phase separation behavior leads to the formation of protein‐surfactant coacervates. [ 25 , 26 ] The water content was ≈30 % (w/w) in the SUP‐surfactant complexes as determined by thermogravimetric analysis (TGA) (Figure S3). After lyophilizing for ≈30 min, ≈14 % of water remained in the coacervate (Figure S4), resulting in the formation of the protein‐based adhesive (Figure 1 C ).…”

Genetically Engineered Polypeptide Adhesive Coacervates for Surgical Applications

“…This liquid-liquid phase separation behavior leads to the formation of proteinsurfactant coacervates. [25,26] Thew ater content was % 30 % (w/w) in the SUP-surfactant complexes as determined by thermogravimetric analysis (TGA) (Figure S3). After lyophilizing for % 30 min, % 14 %o fw ater remained in the coacervate (Figure S4), resulting in the formation of the proteinbased adhesive (Figure 1C).…”

Genetically Engineered Polypeptide Adhesive Coacervates for Surgical Applications

“…The wetting environment may lead to the failure of pressure‐sensitive adhesion because the hydration of the polymers or swelling of the adhesive will hinder the formation of the interactions between the adhesive and target surface; therefore, strong adhesion is usually achieved in the dry state. [ 1 ] Recently, increasing studies have been focused on the engineering underwater adhesives and different methods such as surface drainage architecture design, [ 2–4 ] catechol chemistry, [ 5–7 ] hydrophobic adjustment, [ 8,9 ] water‐displacing [ 10,11 ] was proposed. However, many of the adhesives are only used at room temperature and their underwater adhesion performance under extreme temperature are unknown or unexplored.…”

“…surface; therefore, strong adhesion is usually achieved in the dry state. [1] Recently, increasing studies have been focused on the engineering underwater adhesives and different methods such as surface drainage architecture design, [2][3][4] catechol chemistry, [5][6][7] hydrophobic adjustment, [8,9] water-displacing [10,11] was proposed. However, many of the adhesives are only used at room temperature and their underwater adhesion performance under extreme temperature are unknown or unexplored.…”

Polymer Pressure‐Sensitive Adhesive with A Temperature‐Insensitive Loss Factor Operating Under Water and Oil