Photocrosslinkable and hydroplasicable UV-shielding nanocellulose films facilitated by hydroxyl-yne click reaction

Direct ink writing of a bio-based ink made of low concentration cellulose nanofiber crosslinked with poly (ethylene glycol) via hydroxyl-yne click chemistry

Achieving both low solid content and printability for cellulose nanofiber inks remains challenging. In this study, mild hydroxyl-yne click chemistry was used to chemically crosslink dipropiolate ester of polyethylene glycol (DA-PEG) with 2,2,6,6-tetramethyl-1-piperidinyloxy (TEMPO) oxidized cellulose nanofibers (TOCN), forming TOCN-PEG (TP) inks. This crosslinking network allowed for effective viscosity control, with TP ink viscosity increasing by 128.5 % upon PEG addition. As a result, direct ink writing (DIW) 3D printing of TOCN was feasible at low concentrations (1.0-2.0 wt%). The printed TP hydrogel scaffolds exhibited high mechanical strength, bearing loads over 500 times their weight, and fluorescence due to conjugated double bonds and carbonyl groups. Additionally, cell viability rates exceeded 96 % at 24 h and 93 % at 48 h, indicating non-cytotoxicity (viability >80 %). Thus, the easily customizable TP inks prepared via hydroxyl-yne click chemistry hold promise for various applications, especially in 3D-printed bio-cellular scaffolds.

Loading curcumin on hyperbranched polymers functionalized Zein via the phenol-yne click reaction as pH-responsive drug delivery system for chemotherapy and photodynamic therapy

Zein and its complexes have been considered as promising carriers for encapsulating and delivering various biological active ingredients, however, there still have some issues about Zein-based drug delivery systems should be considered, including poor colloidal stability, low drug encapsulation efficiency as well as rapid initial drug release, and uncontrollable release. In this work, we reported for the first time that hyperbranched polymers (HPG) functionalized Zein with terminal alkyne (Zein-HPG-PA) can be used for loading anticancer agent curcumin (CUR) via a facile phenol-yne click reaction. The resultant product (Zein-HPG-PA@CUR) displays high drug loading capacity, small particle size and excellent water dispersibility. More importantly, almost no CUR was released from Zein-HPG-PA@CUR under pH 7.4 and the cargo will be gradually released under acidic environment. As compared with free CUR, Zein-HPG-PA@CUR shows considerable cytotoxicity towards MDA-MB-231 cells under dark environment, while the cytotoxicity was significantly enhanced upon light-irradiation, implying great potential of Zein-HPG-PA@CUR for cancer treatment. Considered the above aspects, we believe that this work should be of significant impact on the biomedical applications of Zein, especially for fabrication of Zein-based responsive drug delivery systems.

Efficient fabrication of chitin-based films with high UV-blocking and fluorescence via Hantzsch reaction

As the second most abundant polysaccharide on earth, chitin-based films are promising packaging and biomedical materials. However, the lack of special function (especially UV-blocking properties and fluorescence) usually restricts their further and high-value applications. Herein, high UV-blocking and fluorescence chitin-based films were fabricated via surface modification using acetoacetation and the Hantzsch reaction. The structure and properties of the films were characterized by NMR, FTIR, fluorescence spectrum, and tensile tests. The results showed that the benzene ring and 1,4-dihydropyridine ring (DHP) were successfully grafted on the films in the mild process. Besides, the degree of substitution of DHP (DSDHP) increased with the reaction time, temperature, and substrate concentration. Moreover, the modification followed a first-order reaction at 20 °C with a rate constant of 2.1 × 10-4. When the DSDHP was over 0.029, the films exhibited 100 % UV shielding. The fluorescence spectrum demonstrated that the films had excellent solvent and temperature resistance. In addition, the films exhibited excellent mechanical strength with tensile strength up to 85.2 MPa. This work provides a facile and environmentally friendly strategy to fabricate a functional chitin-based film with potential applications in UV protection, medical packaging, and fluorescent materials.

A tough, reversible and highly sensitive humidity actuator based on cellulose nanofiber films by intercalation modulated plasticization

Cellulose nanofiber was an ideal candidate for humidity actuators based on its wide availability, biocompatibility and excellent hydrophilicity. However, conventional cellulose nanofiber-based actuators faced challenges like poor water resistance, flexibility, and sensitivity. Herein, water-resistant, flexible, and highly sensitive cross-linked cellulose nanofibers (CCNF) single-layer humidity actuators with remarkable reversible humidity responsiveness were prepared by combining the green click chemistry modification and intercalation modulated plasticization (IMP). The incorporation of phenyl ring and the crosslinked network structure in CCNF films contributed to its improved water resistance and mechanical properties (with a stress increased from 85.9 ± 3.1 MPa to 141.2 ± 21.5 MPa). SEM analysis confirmed enhanced interlaminar sliding properties facilitated by IMP. This resulted in increased flexibility and toughness of CCNF films, with a strain of 11.5 % and toughness of 9.9 MJ/m3. These improvements efficiently enhanced humidity sensitivity for cellulose nanofiber, with a 4.8-fold increase in bending curvature and a response time of only 3.4 ± 0.1 s. Finally, the good humidity sensitivity of modified CNF can be easily imparted to carbon nanotubes (CNTs) via simple self-assembly method, thus leading to a high-performance humidity-responsive actuator. The click chemistry modification and IMP offer a new avenue to fabricate tough, reversible and highly sensitive humidity actuator based on cellulose nanofiber.