Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12

Sevda Akay Sazaklioglu

doi:10.54187/jnrs.1789315

Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12

Abstract

This study covers the development of a hybrid analysis method aimed at determining Vitamin B12 (cyanocobalamin) by utilizing both its chemical structure and redox properties. In the first stage of the study, a calibration curve was created over the characteristic absorbance peaks at a wavelength of 361 nm using ultraviolet-visible (UV-Vis) spectrophotometry. This curve was used as a reference for method accuracy and quantitative determination. In the second stage, an electrochemical reduction process was performed by utilizing the electroactive nature of Vitamin B12. In this process, the cobalt ion in the molecule was reduced from Co (III) to Co (II) by applying a certain potential to the solution. After the electrochemical process, the sample solutions were re-analyzed using a UV-Vis spectrophotometer, and the changes in the spectrum were examined. A significant improvement in analytical performance was observed when using the rB12 form. While the detection limit for B12 was determined as 0.004 mM, the linear range was 0.012–0.01 mM, and the correlation coefficient was 0.9975, the detection limit for rB12 decreased to 0.002 mM, the linear working range widened to 0.006–0.1 mM, and the correlation coefficient increased to 0.9993. Notably, the reduced form of B12 exhibited superior analytical performance compared to the non-reduced form, with improved sensitivity, wider linear range, and lower detection limit, highlighting the method’s enhanced applicability to redox-responsive analytes. This method also contributes to the development of new generation hybrid analysis methods for vitamins, pharmaceutical active ingredients, and biomolecules with redox properties.

Keywords

Vitamin B12, cobalamin, UV-Vis spectrophotometry, electrochemical reduction

Ethical Statement

No approval from the Board of Ethics is required.

Thanks

I would like to thank Prof. Dr. Hüseyin Çelikkan for his kind support and helpful contributions during the preparation of this work.

References

Z. Fan, Y. Li, X. Fan, P. Wang, R. Yang, C. Xie, Simultaneous determination of three active forms of vitamin B12 in situ produced during fermentation by LC-MS/MS, Foods 14 (2) (2025) 309.
A. R. Mathew, G. D. Matteo, P. L. Rosa, S. A. Barbati, L. Mannina, S. Moreno, A. M. Tata, V. Cavallucci, M. Fidaleo, Vitamin B12 deficiency and the nervous system: Beyond metabolic decompensation—comparing biological models and gaining new insights into molecular and cellular mechanisms, International Journal of Molecular Sciences 25 (1) (2024) 590.
P. B. K. Chau, T. H. Vu, M. II Kim, Highly efficient fluorescent detection of vitamin B12 based on the inner filter effect of dithiol-functionalized silver nanoparticles, Nanomaterials 13 (17) (2023) 2444.
Y. Guo, Y. Li, Y. Xiang, Advances in fluorescent nanosensors for detection of vitamin B12, Critical Reviews in Analytical Chemistry 55 (5) (2025) 945-955.
R. Green, L. H. Allen, A. L. Bjørke-Monsen, A. Brito, J. L. Guéant, J. W. Miller, A. M. Molloy, E. Nexo, S. Stabler, …, C. Yajnik, Vitamin B12 deficiency, Nature Reviews Disease Primers 3 (2017) 17040.
G. G. Mohamed, A. M. Fekry, F. M. A. Attia, N. S. Ibrahim, S. M. Azab, Simultaneous determination of some antidepressant drugs and vitamin B12 in pharmaceutical products and urine sample using HPLC method, Journal of Chromatography B 1150 (2020) 122178.
N. Pourreza, R. Mirzajani, J. Burromandpiroze, Fluorescence detection of vitamin B12 in human plasma and urine samples using silver nanoparticles embedded in chitosan in micellar media, Analytical Methods 9 (27) (2017) 4052–4059.
S. M. Mandal, M. Mandal, A. K. Ghosh, S. Dey, Rapid determination of vitamin B2 and B12 in human urine by isocratic liquid chromatography, Analytica Chimica Acta 640 (1–2) (2009) 110–113.
A. K. Offringa, A. R. Bourgonje, M. S. Schrier, R. C. Deth, H. van Goor, Clinical implications of vitamin B12 as redox-active cofactor, Trends in Molecular Medicine 27 (10) (2021) 931–934.
R. Banerjee, H. Gouda, S. Pillay, Redox-linked coordination chemistry directs vitamin B12 trafficking, Accounts of Chemical Research 54 (8) (2021) 2003–2013.

Y. V. Shatalin, V. S. Shubina, M. E. Solovieva, V. S. Akatov, The redox-catalytic properties of cobalamins, Molecular Biology 57 (6) (2023) 1038–1051.
M. Koutmos, S. Datta, K. A. Pattridge, J. L. Smith, R. G. Matthews, Insights into the reactivation of cobalamin-dependent methionine synthase, PNAS Proceedings of the National Academy of Sciences of the United States of America 106 (44) (2009) 18527–18532.
M. J. Weidemann, R. Hems, D. L. Williams, H. A. Krebs, Gluconeogenesis from propionate in kidney and liver of the vitamin B12-deficient rat, Biochemical Journal 117 (1) (1970) 177–181.
Y. Albawarshi, A. Amr, K. Al-Ismail, M. Shahein, M. Majdalawi, M. Saleh, A. Khamaiseh, B. El-Eswed, Simultaneous determination of B1, B2, B3, B6, B9, and B12 vitamins in premix and fortified flour using HPLC/DAD: Effect of detection wavelength, Journal of Food Quality 2022 (1) (2022) 9065154.
L. Zhang, H. Wang, Q. Hu, X. Guo, L. Li, S. Shuang, X. Gong, C. Dong, Carbon quantum dots doped with phosphorus and nitrogen are a viable fluorescent nanoprobe for determination and cellular imaging of vitamin B12 and cobalt (II), Microchimica Acta 186 (2019) 506.
S. Antherjanam, B. Saraswathyamma, R. G. Krishnan, G. M. Gopakumar, Electrochemical sensors as a versatile tool for the quantitative analysis of vitamin B12, Chemical Papers 75 (7) (2021) 2981–2995.
D. Kong, L. Liu, S. Song, H. Kuang, C. Xu, Development of sensitive, rapid, and effective immunoassays for the detection of vitamin B12 in fortified food and nutritional supplements, Food Analytical Methods 10 (1) (2017) 10–18.
J. V. Wyk, T. J. Britz, A rapid HPLC method for the extraction and quantification of vitamin B12 in dairy products and cultures of Propionibacterium freudenreichii, Dairy Science and Technology 90 (5) (2010) 509–520.
B. Dhuva, S. Obrai, Innovative cerium and chromium co-doped carbon quantum dots: Synthesis, smartphone-compatible and sensitive fluorescence approach for detection of vitamin B12, Journal Fluorescence 35 (9) (2025) 7517–7530.
S. Alshehri, M. Shariq, W. Al-Gethami, A. H. Al-Moubaraki, M. D. Alshahrani, N. Alharbi, H. S. Alzahrani, N. Al-Qasmi, Fluorescent yttrium oxide nanoparticles for sensitive detection of vitamin B12: Synthesis, characterization, and sensor development, Materials Science–Poland 43 (3) (2025) 202–215.
E. Gökoğlu, S. Ş. Budun, B. Doyuran, T. Taskin-Tok, Fluorescence studies on the binding affinity and determination of vitamin B12 in the presence of fibrinogen, Journal of Fluorescence 35 (6) (2025) 4375–4383.
S. M. T. Gharibzahedi, G. K. Hasabnis, E. Akin, Z. Altintas, Molecularly imprinted polymers-based electrochemical sensors for tracking vitamin B12 released from spray-dried microcapsules during in vitro simulated gastrointestinal digestion, Sensing and Bio-Sensing Research 47 (2025) 100759.
M. D. Harfiansyah, E. D. L. Putra, S. M. Sinaga, Simultaneous determination of vitamins B1, B2, B3, B6, and B12 in tablet forms using the area under the curve ultraviolet spectrophotometry method, International Journal of Research and Review 11 (12) (2024) 56–61.

Details

Primary Language

English

Subjects

Instrumental Methods

Journal Section

Research Article

Authors

Sevda Akay Sazaklioglu ^*
0000-0003-0924-1276
Türkiye

Publication Date

April 30, 2026

Submission Date

September 22, 2025

Acceptance Date

April 8, 2026

Published in Issue

Year 2026 Volume: 15 Number: 1

DOI

https://doi.org/10.54187/jnrs.1789315

IZ

https://izlik.org/JA49ZK44LM

APA

Akay Sazaklioglu, S. (2026). Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12. Journal of New Results in Science, 15(1), 41-53. https://doi.org/10.54187/jnrs.1789315

AMA

1.Akay Sazaklioglu S. Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12. JNRS. 2026;15(1):41-53. doi:10.54187/jnrs.1789315

Chicago

Akay Sazaklioglu, Sevda. 2026. “Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12”. Journal of New Results in Science 15 (1): 41-53. https://doi.org/10.54187/jnrs.1789315.

EndNote

Akay Sazaklioglu S (April 1, 2026) Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12. Journal of New Results in Science 15 1 41–53.

IEEE

[1]S. Akay Sazaklioglu, “Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12”, JNRS, vol. 15, no. 1, pp. 41–53, Apr. 2026, doi: 10.54187/jnrs.1789315.

ISNAD

Akay Sazaklioglu, Sevda. “Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12”. Journal of New Results in Science 15/1 (April 1, 2026): 41-53. https://doi.org/10.54187/jnrs.1789315.

JAMA

1.Akay Sazaklioglu S. Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12. JNRS. 2026;15:41–53.

MLA

Akay Sazaklioglu, Sevda. “Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12”. Journal of New Results in Science, vol. 15, no. 1, Apr. 2026, pp. 41-53, doi:10.54187/jnrs.1789315.

Vancouver

1.Sevda Akay Sazaklioglu. Direct and Cobalt-Reduction Based Spectroscopic Determination of Vitamin B12. JNRS. 2026 Apr. 1;15(1):41-53. doi:10.54187/jnrs.1789315