Structural and mechanical properties of gelatin composite films

Keywords: insulin, encapsulation, film, rheology, gelatin, chitosan, citric acid, L-glutamic acid

Abstract

The deformation properties, elastic modulus and strength of gelatin films with chitosan, citric acid and L-glutamic acid were studied. According to the results of the study, it was found that the addition of chitosan, citric and L-glutamic acid increases the strength and elasticity modulus of gelatin films. Assessment of the pH effect on the gelatin - chitosan, gelatin - citric acid and gelatin - L-glutamic acid systems provide a representation of their changes in these media. It is assumed that gelatin with L-glutamic acid forms a strong structure at low pH and withstands the conditions of the acidic environment of the stomach, while in an alkaline environment the structural and mechanical characteristics of this system decrease, creating favorable conditions for the release of encapsulated insulin in the intestinal phase. The changes of the physicochemical, structural and mechanical properties of the films under simulated gastrointestinal conditions (pH = 1.0; 4.01; 6.86; 9.18) were determined by IR spectroscopy. The observability of the bands of С-Н, С-ОН, С=O, C-N, N-H, СН(NH2), CH2OH groups in the infrared spectra of films in various pH media is associated with an increase of intermolecular hydrogen bonds and the formation of associative structures.

References

1 International Diabetes Federation. Diabetes Atlas 2021. 10th edition. ISBN 978-2-930229-98-0

2 American diabetes association (2006) Diabetes Care 29:2140-2157. Crossref

3 Sheeja VS, Reddy MH, Joseph J, Reddy D (2010) International Journal of Pharmaceutical Sciences Review and Research 2:98-105.

4 van Belle TL, Coppieters KT, von Herrath MG (2011) Physiol Rev 91:79-118. Crossref

5 Peyrot M, Barnett AH, Meneghini LF, Schumm-Draeger PM (2012) Diabetes, Obesity and Metabolism 14:1081-1087. Crossref

6 Brange J, Langkjaer L (1997) Insulin Formulation and Delivery. Plenum Press, New York, USA. P.343-410

7 Sajeesh S, Sharma CP (2006) Int J Pharm 325:147-154. Crossref

8 Singh S, Patel D, Patel NR, Kumar K, Kumar Gautam M (2010) International Journal Of Pharma Professional’s Research 1:46-51.

9 Sarmento B, Ribeiro A, Veiga F, Sampaio P, Neufeld R, Ferreira D (2007) Pharm Res 24:2198-2206. Crossref

10 Almeida H, Amaral MH, Lobão P (2012) Journal of Applied Pharmaceutical Science 2:01–10. Crossref

11 Reis CP, Ribeiro AJ, Neufeld RJ, Veiga F (2007) Biotechnol Bioeng 96:977-989. Crossref

12 Dai C, Wang B, Zhao H, Li B, Wang J (2006) Colloid Surface B 47:205-210. Crossref

13 Dang J, Leong K (2006) Adv Drug Deliver Rev 58:487-499. Crossref

14 Wei Y, Sun C, Dai L, Zhan X, Gao Y (2018) Food Hydrocolloids 81:149-158. Crossref

15 Ciriminna R, Meneguzzo F, Delisi R, Pagliaro M (2017) Chem Cent J 11:22. Crossref

16 Korithoski B, Krastel K, Cvitkovitch DG (2005) J Bacteriol 187:4451-4456. Crossref

17 Long B, Li J, Song Y, Du J (2011) Ind Eng Chem Res 50:8354-8360. Crossref

18 Nisar S, Pandit AH, Nadeem M, Pandit AH, Rizvi MMA, Rattan S (2021) Int J Biol Macromol 182:37-50. Crossref

19 Dyakina TA, Derkatch SR, Levachev SM (2004) Bulletin of Moscow University [Vestnik Moskovskogo universiteta] 45:452-456. (In Russian)

20 Matveyenko VN, Kirsanov YeA, Remizov SV (2006) Bulletin of Moscow University [Vestnik Moskovskogo universiteta] 47:393-397. (In Russian)

21 Maji K, Dasgupta S (2019) J Mater Res 34:2807-2818. Crossref

22 Tolstoy VP, Chernyshova IV, Skryshevsky VA (2003) Handbook of Infrared Spectroscopy of Ultrathin Films. John Wiley & Sons, Inc. Publication, Hoboken, New Jersey, USA. Crossref

23 Stuart BH (2004) Infrared Spectroscopy: Fundamentals and Applications. John Wiley & Sons, Ltd, Chichester, UK. Crossref

24 Rousi Z, Malhiac C, Fatouros DG, Paraskevopoulou A (2019) Food Hydrocolloids 96:577-588. Crossref

25 Rohman A, Man YBC (2010) Food Res Int 43:886-892. Crossref
Published
2022-12-03
How to Cite
Yerlan, G., Tyussyupova, B., Tazhibayeva, S., Musabekov, K., & Balabushevich, N. (2022). Structural and mechanical properties of gelatin composite films. Chemical Bulletin of Kazakh National University, 107(4), 30-39. https://doi.org/https://doi.org/10.15328/cb1267