Progress in chitin/chitosan and their derivatives for biomedical applications: Where we stand

“…Meanwhile, the red blood cells adhere to the chitosan threads due to the Coulomb attractive force because they have opposite charges, coating one or, at most, several layers of red blood cells on the gauze. At the same time, H+ ions are continuously released from the chitosan (associated with NH 3 molecules) into the blood, reducing the negative charges on the surrounding red blood cells (associated with COO molecules) and thus the repulsive electrical force of the double layer between the red blood cells [33]. As a result, the red blood cells in the vicinity of the gauze aggregate with each other and adhere to the layer(s) previously smeared on the gauze.…”

Chitosan Hemostatic Dressings: Properties and Surgical Applications

“…Meanwhile, the red blood cells adhere to the chitosan threads due to the Coulomb attractive force because they have opposite charges, coating one or, at most, several layers of red blood cells on the gauze. At the same time, H+ ions are continuously released from the chitosan (associated with NH 3 molecules) into the blood, reducing the negative charges on the surrounding red blood cells (associated with COO molecules) and thus the repulsive electrical force of the double layer between the red blood cells [33]. As a result, the red blood cells in the vicinity of the gauze aggregate with each other and adhere to the layer(s) previously smeared on the gauze.…”

Chitosan Hemostatic Dressings: Properties and Surgical Applications

Preparation of graphene/carbon nanotube-cellulose composites assisted by ionic liquids: A review

Hybrid construction of tissue-engineered nerve graft using skin derived precursors induced neurons and Schwann cells to enhance peripheral neuroregeneration