Fluorophenylboronic acid substituted chitosan for insulin loading and release

Phenylboronic acid (PBA) can form dynamical reversible chemical bonds with sugars, and has potential in glucose response and controlling insulin delivery. In this paper, 4-fluorophenylboronic acid (FPBA) was employed which could work better than normal PBA in physiological environment. Herein, FPBA-...

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Bibliographic Details
Published in:Reactive & functional polymers 2020-01, Vol.146, p.104435, Article 104435
Main Authors: Luo, Lei, Song, Rijian, Chen, Jiajie, Zhou, Benyu, Mao, Xuan, Tang, Shunqing
Format: Article
Language:English
Subjects:
Chemical bonds
Chitosan
Controlled release
Fluorophenylboronic acid
Glucose
Hydroxyl groups
Insulin
Molecular weight
Organic chemistry
Raw materials
Reaction time
Substitution reactions
Sugar
Zeta potential
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Summary:Phenylboronic acid (PBA) can form dynamical reversible chemical bonds with sugars, and has potential in glucose response and controlling insulin delivery. In this paper, 4-fluorophenylboronic acid (FPBA) was employed which could work better than normal PBA in physiological environment. Herein, FPBA-substituted chitosans (CS-FPBA) with three different molecular weights were prepared, and affecting factors on preparation, including solvent, pH, raw materials ratio, activation time and reaction time, were discussed. The glucose responsiveness and controlling insulin release properties of CS-FPBA were also determined. Results showed that the substitution of FPBA onto CS could decrease the zeta potential of CS to negative values, which was favorable for CS-FPBA to react with hydroxyl groups in biological environments. They could effectively load with insulin with approximately 50% (wt%) encapsulation efficiency in 0.5 mg/mL insulin. Also, CS-FPBA particles had significant binding efficiency to glucose, which was dramatically higher by over 6 folds compared to chitosan. The maximum releasing amount of insulin was >90% in 9 h in 3 mg/mL of glucose solution when the molecular weight of CS was 50 kDa. In summary, CS-FPBA has potential to control the release of insulin, and can regulate the release rate by controlling the molecular weight of CS. •CS-FPBA could be responsive to glucose better than normal CS-PBA in physiological environment.•CS-FPBA could effectively load with insulin with approximately 50% (wt%) encapsulation efficiency in 0.5 mg/mL insulin.•Insulin release speed could be regulated by choosing different molecular weights.•The zeta potential of CS-FPBA was 6.7~7.1, lower than physiological pH (7.4).•CS-FPBA could appear various morphologies in different substituted degree.
ISSN:1381-5148
1873-166X
DOI:10.1016/j.reactfunctpolym.2019.104435