A facile and efficient strategy to encapsulate the model basic protein lysozyme into porous CaCO<sub>3</sub>

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • Pengzhong Shi - , Wenzhou Medical University, University of Chinese Academy of Sciences (Author)
  • Shan Luo - , Wenzhou Medical University (Author)
  • Brigitte Voit - , Chair of Organic Chemistry of Polymers, Leibniz Institute of Polymer Research Dresden (Author)
  • Dietmar Appelhans - , Leibniz Institute of Polymer Research Dresden (Author)
  • Xingjie Zan - , Wenzhou Medical University, University of Chinese Academy of Sciences (Author)

Abstract

Basic proteins play important roles in biological activities and disease treatment, but their high sensitivity to the body environment and short life time have limited their applications. Encapsulating the proteins into carriers has been demonstrated to be an effective way to prolong the protein half life time and to control the release temporally and spatially. However, fabricating protein carriers with high protein loading efficacy under mild conditions is still a big challenge. The capsules generated by the combination of the layer by layer (LBL) technique and sacrificial templates have been extensively investigated for the encapsulation of proteins. Porous CaCO3 is an effective sacrificial template with the ability to load various drugs efficiently under mild conditions, but it shows very poor ability in loading basic proteins. Here, we developed a highly efficient but very simple method to encapsulate lysozyme into porous CaCO3. An efficiency of 99.5% and capacity of 91.6 mg g(-1) under very gentle conditions were obtained by doping heparin into porous CaCO3. Most importantly, the activity of the encapsulated lysozyme was almost 100% retained. Furthermore, we evaluated the encapsulation efficiency of the loaded lysozyme during the LBL wrapping process and demonstrated that the loss of the loaded lysozyme was controllable by choosing suitable polyelectrolyte pairs. Considering the multi-interaction mode of heparin with various proteins and the ability to retain the function of the loaded protein demonstrated in our study, we believe that the developed approach has great potential for encapsulating various functional proteins with a wide range of applications in catalysis, disease treatment, and tissue engineering.

Details

Original languageGerman
Pages (from-to)4205-4215
Number of pages11
JournalJournal of Materials Chemistry B
Volume6
Issue number25
Publication statusPublished - 7 Jul 2018
Peer-reviewedYes

External IDs

PubMed 32254594
Scopus 85049259413
ORCID /0000-0002-4531-691X/work/148608066

Keywords

Keywords

  • Calcium-carbonate microparticles, Polyelectrolyte multilayer films, Drug-delivery, In-vivo, Microcapsules, Capsules, Enzyme, Particles, Growth, Adsorption