Surface modified materials for active capture of enzymes

• Published in: Journal of materials chemistry. B, Materials for biology and medicine Vol. 11; no. 11; pp. 2377 - 2388
• Main Authors: Wang, Dandan, Hartz, William F, Moloney, Mark G
• Format: Journal Article
• Language: English
• Published: England Royal Society of Chemistry 15.03.2023
• Subjects: Acrylic resins; Carboxyl group; Cellulase; Cellulase - chemistry; Coupling agents; Enzymatic activity; Enzyme activity; Enzymes; Enzymes, Immobilized - chemistry; Fluorescence; Glass fiber reinforced plastics; Glass wool; Immobilization; Membranes; Optimization; Polyacrylate; Polystyrene; Polystyrene resins; Polytetrafluoroethylene; Proteins; Reagents; Spectra; Surface chemistry
• ISSN: 2050-750X; 2050-7518
• DOI: 10.1039/d2tb02550g

The insertion of bis(diarylcarbene)s onto a glass fiber (GF) membrane surface provided an active coating for the direct capture of protein - exemplified by the enzyme, cellulase - through a mild diazonium coupling process which does not require additional coupling agents. Successful cellulase attachment on the surface was demonstrated by the disappearance of diazonium and formation of azo functions in the N 1s high resolution spectra, the appearance of carboxyl group in C 1s spectra, both observed by XPS; the -C&z.dbd;O vibrational bond observed by ATR-IR; as well as the observation of fluorescence. Further, five support materials (polystyrene XAD4 bead, polyacrylate MAC3 bead, glass wool, glass fiber membrane, polytetrafluoroethylene membrane) with different morphology and surface chemistry, were examined in detail as supports for cellulase immobilization using this common surface modification protocol. Of interest is that such covalently bound cellulase on modified GF membrane gave both the highest enzyme loading (∼23 mg cellulase per g support), and retained more than 90% of activity after 6 cycles of re-use, compared with substantial loss of enzyme activity for physiosorbed cellulase after 3 cycles. Optimization of the degree of surface grafting and the effectiveness of a spacer between surface and enzyme for enzyme loading and activity were conducted. This work shows that carbene surface modification is a viable strategy for introducing enzymes onto a surface under very mild conditions and retaining a meaningful level of activity, and particularly, using GF membrane as a novel support provides a potential platform for enzyme and protein immobilization. The insertion of bis(diarylcarbene)s onto a glass fiber (GF) membrane surface provided an active coating for the direct capture of protein - exemplified by the enzyme, cellulase - through a mild diazonium coupling process which does not require additional coupling agents.