. 2023 Feb 10;6(1):28.

doi: 10.1038/s42004-023-00829-1.

Multi-responsive chitosan-based hydrogels for controlled release of vincristine

Bahareh Farasati Far¹, Mohsen Omrani¹, Mohammad Reza Naimi Jamal², Shahrzad Javanshir³

Affiliations

¹ Research Laboratory of Green Organic Synthesis & Polymers, Department of Chemistry, Iran University of Science and Technology, 16846-13114, Tehran, Iran.
² Research Laboratory of Green Organic Synthesis & Polymers, Department of Chemistry, Iran University of Science and Technology, 16846-13114, Tehran, Iran. naimi@iust.ac.ir.
³ Pharmaceutical and Heterocyclic Compounds Research Laboratory, Department of Chemistry, Iran University of Science and Technology, 16846-13114, Tehran, Iran. shjavan@iust.ac.ir.

PMID: 36765265
PMCID: PMC9918727
DOI: 10.1038/s42004-023-00829-1

Multi-responsive chitosan-based hydrogels for controlled release of vincristine

Bahareh Farasati Far et al. Commun Chem. 2023.

. 2023 Feb 10;6(1):28.

doi: 10.1038/s42004-023-00829-1.

Authors

Bahareh Farasati Far¹, Mohsen Omrani¹, Mohammad Reza Naimi Jamal², Shahrzad Javanshir³

Affiliations

¹ Research Laboratory of Green Organic Synthesis & Polymers, Department of Chemistry, Iran University of Science and Technology, 16846-13114, Tehran, Iran.
² Research Laboratory of Green Organic Synthesis & Polymers, Department of Chemistry, Iran University of Science and Technology, 16846-13114, Tehran, Iran. naimi@iust.ac.ir.
³ Pharmaceutical and Heterocyclic Compounds Research Laboratory, Department of Chemistry, Iran University of Science and Technology, 16846-13114, Tehran, Iran. shjavan@iust.ac.ir.

PMID: 36765265
PMCID: PMC9918727
DOI: 10.1038/s42004-023-00829-1

Abstract

As medical research progresses, the derivation and development of biological materials such as hydrogels have steadily gained more interest. The biocompatibility and non-toxicity of chitosan make chitosan hydrogels potential carriers for drug delivery. This work aims to develop two multi-reactive, safe, and highly swellable bio-hydrogels consisting of chitosan-graft-glycerol (CS-g-gly) and carboxymethyl chitosan-graft-glycerol (CMCS-g-gly), for sustained and controlled drug release, improved bioavailability along with entrapment in nanocarriers, which reduces side effects of vincristine sulphate. CS-g-gly and CMCS-g-gly are successfully prepared and fully characterized using analytical techniques. Under various conditions, the prepared hydrogels exhibit a high swelling ratio. Vincristine-loaded CS-g-gly (VCR/CS-g-gly), and CMCS-g-gly (VCR/CMCS-g-gly) show high encapsulation efficiency between 72.28-89.97%, and 56.97-71.91%, respectively. VCR/CS-g-gly show a sustained release behavior, and the maximum release of VCR from hydrogels reached 82% after 120 h of incubation. MCF-7 (breast cancer cell line) and MCF-10 (normal breast cell line) are evaluated for cell viability and apoptosis induction. The in-vitro anti-tumor efficacy is investigated using flow cytometry. The tetrazolium-based MTT assay of hydrogels shows no evidence of significant cytotoxicity in MCF-7 and MCF-10 cells. According to these findings, these hydrogels can effectively deliver drugs to MCF-7 and other breast cancer cells.

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Conflict of interest statement

The authors declare no competing interests.

Figures

**Fig. 1. Synthesis pathway of hydrogels.**
a CS-g-gly, (b) CMCS-g-gly.

**Fig. 2. Design strategy for CS-g-gly and CMCS-g-gly hydrogels.**
a Gelling of CS and (b) gelling of CMCS-g-gly with NH4 + binder after 48 h.

**Fig. 3. FT-IR spectra of the synthesized hydrogels.**
a Chitosan, (b) Glycerol, (c) CS-g-gly, (d) CMCS, (e) CMCS-g-gly.

**Fig. 4. ¹HNMR spectra of hydrogels.**
a CS-g-gly and (b) CMCS-g-gly (500 MHz, D2O, 25 °C).

**Fig. 5. SEM morphological characterization of Hydrogels.**
a CS-g-gly, (b) VCR/CS-g-gly, (c) CMCS-g-gly, (d) VCR/CMCs-g-gly.

**Fig. 6. Loaded and unloaded hydrogels obtained responses under the optimal conditions.**
a hydrogel size, (b) Zeta potential, and (c) Polydispersity, (d) Schematic representation of zeta potential. Data represent means ± standard deviations (n = 3). For all charts, ***p < 0.001; **p < 0.01; *p < 0.05.

**Fig. 7. Atomic force microscopy (AFM) images.**
a CS-g-gly and (b) CMCS-g-gly hydrogels showing nanoparticles morphologies, TGA and DTG of (c) CS-g-gly and (d) CMCS-g-gly hydrogels.

**Fig. 8. The effect of pH on swelling behavior, EWC and SR of hydrogels.**
a CS-g-gly dry tablet in pH = 1.2, pH = 5 and pH = 7.4 after 24 h, (b) CMCS-g-gly dry tablet in pH = 5 and pH = 7.4 after 24 h, (c) CS-g-gly EWC (%), (d) CS-g-gly SR (%), (e) CMCS-g-gly EWC (%), (f) CMCS-g-gly SR (%), in different pH. Each experiment was performed and replicated three times, and the results were displayed using error bars to depict the variance.

**Fig. 9. The effect of temperature on swelling behavior of hydrogels.**
a CS-g-gly dry tablet, (b) CMCS-g-gly dry tablet, (c) CS-g-gly EWC (%), (d) CS-g-gly SR (%) (e) CMCS-g-gly EWC (%), (f) CMCS-g-gly SR (%), in different temperature after 2 and 5 h. Each experiment was performed and replicated three times, and the results were displayed using error bars to depict the variance.

**Fig. 10. Encapsulation efficiency and drug release profile of prepared hydrogels.**
Encapsulation efficiency of (a) CS-g-gly and (b) CMCS-g-gly. Drug release profile of (c) VCR/CS-g-gly and (d) VCR/CMCS-g-gly and free VCR in PBS (pH 7.4 and 5) after 120 h. Each value represents the mean ± SD of three independent experiments.

**Fig. 11. Comparison of cytotoxic effect.**
a, b Cs-g-gly, CMCS-g-gly, VCR/Cs-g-gly and VCR/CMCS-g-gly against MCF-7 cell lines and (c, d) Cs-g-gly, CMCS-g-gly, VCR/Cs-g-gly and VCR/CMCS-g-gly against MCF-10 cell lines, after 24 and 48 h incubation. Each experiment was performed and replicated three times, and the results were displayed using error bars to depict the variance.

**Fig. 12. Annexin-V/-FITC/PI Flow cytometry analysis of MCF-7 breast cancer cells treated with the prepared hydrogels.**
a CS-g-gly, (b) CMCS-g-gly, (c) CS-g-gly loaded with vincristine, and (d) CMCS-g-gly loaded for 48 h. The lower left (Q4) (Annexin−PI−) and the lower right (Q3) (Annexin+PI−) quadrants represent viable cells and early apoptotic cells. The upper right region (Q2) (annexin+PI+) and the upper left (Q1) (annexin− PI+) represent late apoptotic cells and necrotic cells.

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Multi-responsive chitosan-based hydrogels for controlled release of vincristine

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Multi-responsive chitosan-based hydrogels for controlled release of vincristine

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Conflict of interest statement

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