Preview

The Journal of Almaty Technological University

Advanced search

Optimization of parameters for adding low- and high-methoxylated pectins to curd mass for geroprotective purposes

https://doi.org/10.48184/2304-568X-2026-2-85-94

Abstract

Pectins are considered to have geroprotective properties through enterosorption, antioxidant activity and stabilization of milk structure. The aim of the study is to scientifically substantiate the optimal pH, amount and stages of addition of low-methoxylated and high-methoxylated pectin to the curd mass in order to achieve the maximum moisture retention capacity, the lowest syneresis value and improved structural and mechanical properties. The addition of low-methoxylated and high-methoxylated pectin separately and in combination at amounts of 0.25–1.5% was studied at pH 3.0–6.0. In addition, a pH test was carried out in the range of 4.1–4.5 for combined addition. Moisture retention capacity, syneresis, hardness and cohesiveness, and viscosity were evaluated. The uniformity of pectin distribution was controlled by the methylene blue dye method and the Ca-pectate method, and the distribution was recognized as uniform in all samples. The experiments were carried out three times and statistical processing was performed using ANOVA post-hoc with Tukey's criterion (p<0.05). The optimal pH for high-methoxylated pectin was 3.5, for low-methoxylated pectin – 4.6. Within a very narrow pH range of 4.3, the syneresis value was the highest at a 50:50 ratio. The optimal amount of each pectin was 1.0%. Addition at the initial stage (to freshly prepared curd from cow's milk) is effective for both types of pectin, but for combined addition, a method was proposed: adding low-methoxylated pectin to freshly prepared curd, and high-methoxylated pectin to the finished curd mass. At pH 4.3, the 50:50 pectin ratio provided the maximum moisture retention capacity (78.0%), the minimum syneresis (3.2% on the initial day, 8.0% after 14 days) and a hardness of 0.67 N. Compared to the control experiment value of 2.9 mmol/kg, the lipid peroxidation value after 14 days was 1.6 mmol/kg (which is below the oxidation threshold for dairy products of ≤4 mmol/kg). Recommended parameters: total pectin concentration 1.0% (0.5% low-methoxylated pectin + 0.5% high-methoxylated pectin), pH 4.3, addition of low-methoxylated pectin at the initial stage, and high-methoxylated pectin at the final stage. The finished curd mass had improved geroprotective and structural-mechanical characteristics.

About the Authors

S. U. Yerkebayeva
"M.Auezov South Kazakhstan University" non-profit joint stock company
Kazakhstan

 160012, Shymkent, Tauke Khan Avenue, 5



A. T. Otesh
"M.Auezov South Kazakhstan University" non-profit joint stock company
Kazakhstan

 160012, Shymkent, Tauke Khan Avenue, 5



References

1. Yadav K., Yadav S., Anand G., Yadav P. K., Yadav D. Hydrolysis of complex pectin structures: Biocatalysis and bioproducts // Polysaccharide-degrading biocatalysts. - 2023. ‒ P. 205-225. https://doi.org/10.1016/B978-0-323-99986-1.00011-9

2. Freitas C. M. P., Coimbra J. S. R., Souza V. G. L., Sousa R. C. S. Structure and applications of pectin in food, biomedical, and pharmaceutical industry: A review // Coatings. ‒ 2021. ‒ Vol. 11, № 8. ‒ P. 922. https://doi.org/10.3390/coatings11080922

3. Said N. S., Olawuyi I. F., Lee W. Y. Pectin hydrogels: Gel-forming behaviors, mechanisms, and food applications // Gels. ‒ 2023. ‒ Vol. 9, № 9. ‒ P. 732. https://doi.org/10.3390/gels9090732

4. Liang W.-l., Liao J.-s., Qi J.-R., Jiang W.-x., Yang X.-q. Physicochemical characteristics and functional properties of high methoxyl pectin with different degree of esterification // Food Chemistry. ‒ 2022. ‒ Vol. 375. ‒ P. 131806. https://doi.org/10.1016/j.foodchem.2021.131806

5. Krishna Murthy C., Salomi Suneetha D., Vijaya Nirmala P., Tingirikari J. M. R. Low methylated pectin: structure, sources, functional properties, and emerging role in gut health and industrial applications // International Polymer Processing. ‒ 2026. – Vol.41, № 1. – P.1-30. https://doi.org/10.1515/ipp-2025-0083

6. Lootens D., Capel F., Durand D., Nicolai T., Boulenguer P., Langendorff V. Influence of pH, Ca concentration, temperature and amidation on the gelation of low methoxyl pectin // Food hydrocolloids. ‒ 2003. ‒ Vol. 17, № 3. ‒ P. 237-244. https://doi.org/10.1016/S0268-005X(02)00056-5

7. El-Nawawi S., Heikel Y. Factors affecting gelation of high-ester citrus pectin // Process Biochemistry. ‒ 1997. ‒ Vol. 32, № 5. ‒ P. 381-385. https://doi.org/10.1016/S0032-9592(96)00076-3

8. Noor N., Shah A., Gani A., Gani A., Jhan F., ul Ashraf Z., Ashwar B. A., Ganaie T. A. Food biopolymers: Structural, functional and nutraceutical properties: Pectin. – New York: Springer, 2021. ‒ P. 127-171. https://doi.org/10.1007/978-3-030-27061-2

9. Krapivnytska I., Ladyka V., Ianchyk M., Omelchenko S., Melnyk O., Pertsevyi F. Scientific and practical aspects of pectin and pectin products: Monograph. ‒ Kharkiv: Dissa+, 2022. – 228 p. ISBN: 978-617-7927-98-2

10. Kastner H., Kern K., Wilde R., Berthold A., Einhorn-Stoll U., Drusch S. Structure formation in sugar containing pectin gels–Influence of tartaric acid content (pH) and cooling rate on the gelation of high-methoxylated pectin // Food Chemistry. ‒ 2014. ‒ Vol. 144. ‒ P. 44-49. https://doi.org/10.1016/j.foodchem.2013.06.127

11. Capel F., Nicolai T., Durand D., Boulenguer P., Langendorff V. Calcium and acid induced gelation of (amidated) low methoxyl pectin // Food Hydrocolloids. ‒ 2006. ‒ Vol. 20, № 6. ‒ P. 901-907. https://doi.org/10.1016/j.foodhyd.2005.09.004

12. Löfgren C., Hermansson A.-M. Synergistic rheological behaviour of mixed HM/LM pectin gels // Food hydrocolloids. ‒ 2007. ‒ Vol. 21, № 3. ‒ P. 480-486. https://doi.org/10.1016/j.foodhyd.2006.07.005

13. Harte F., Montes C., Adams M., San Martin-Gonzalez M. Solubilized micellar calcium induced low methoxyl-pectin aggregation during milk acidification // Journal of dairy science. ‒ 2007. ‒ Vol. 90, № 6. ‒ P. 2705-2709. https://doi.org/10.3168/jds.2006-629

14. Sultana N. Biological properties and biomedical applications of pectin and pectin-based composites: A review // Molecules. ‒ 2023. ‒ Vol. 28, № 24. ‒ P. 7974. https://doi.org/10.3390/molecules28247974

15. Pratsinis H., Mavrogonatou E., Zervou S.-K., Triantis T., Hiskia A., Kletsas D. Natural Product-Derived Senotherapeutics: Extraction and Biological Evaluation Techniques // Oncogene-Induced Senescence: Methods and Protocols. Part of the book series: Methods in Molecular Biology. - Springer, 2025. – Vol.2906. ‒ P. 315-359. https://doi.org/10.1007/978-1-0716-4426-3_19

16. Tüsiupova B., Artykova D., Tajibaeva S., Musabekov K. Biopolimerler, qauyn ezbesı jáne süzbe negіzіndegі taghamdyq sіrnelerdіń reologıialyq qasıetterі [Rheological Properties of Food Gels Based on Biopolymers, Melon Pulp and Cottage Cheese] // Almaty tehnologıialyq ýnıversıtetіnіń habarshysy. ‒ 2018. - № 3. ‒ B. 37-42. [In Kazakh]

17. Thakur B. R., Singh R. K., Handa A. K., Rao M. Chemistry and uses of pectin—A review // Critical Reviews in Food Science & Nutrition. ‒ 1997. ‒ Vol. 37, № 1. ‒ P. 47-73. https://doi.org/10.1080/10408399709527767

18. Gryger T., Stěnička M., Vincová A., Lorencová E., Šantová K., Salek R.-N. Role of pectin in maintaining the physicochemical, textural, rheological, and organoleptic properties of model quark cheese spreads during simulated vibrations and storage // International Journal of Biological Macromolecules. ‒ 2025. ‒ Vol. 310, Part 3. ‒ P. 143449. https://doi.org/10.1016/j.ijbiomac.2025.143449


Review

For citations:


Yerkebayeva S.U., Otesh A.T. Optimization of parameters for adding low- and high-methoxylated pectins to curd mass for geroprotective purposes. The Journal of Almaty Technological University. 2026;152(2):85-94. (In Kazakh) https://doi.org/10.48184/2304-568X-2026-2-85-94

Views: 60

JATS XML


Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 License.


ISSN 2304-568X (Print)
ISSN 2710-0839 (Online)