CHEMICAL EDUCATION AS A FOUNDATION FOR DEVELOPING RESEARCH COMPETENCE IN MASTER’S STUDENTS OF PHARMACY
No. 3 (2025), THEORETICAL-METHODOLOGICAL FUNDAMENTALS OF HIGHER AND GENERAL SECONDARY EDUCATIO
No. 3 (2025)

CHEMICAL EDUCATION AS A FOUNDATION FOR DEVELOPING RESEARCH COMPETENCE IN MASTER’S STUDENTS OF PHARMACY

THEORETICAL-METHODOLOGICAL FUNDAMENTALS OF HIGHER AND GENERAL SECONDARY EDUCATIO
https://doi.org/10.52726/as.pedagogy/2025.3.5
Published 2025-11-28
Ya. M. PUSHKAROVA
Bogomolets National Medical University
https://orcid.org/0000-0001-9856-7846
PDF

Keywords

дослідницька компетентність, хімічна освіта, фармацевтична освіта, практико-орієнтований підхід, професійна освіта research competence, chemical education, pharmaceutical education, practice-oriented approach, professional education

How to Cite

PUSHKAROVA Я. М. (2025). CHEMICAL EDUCATION AS A FOUNDATION FOR DEVELOPING RESEARCH COMPETENCE IN MASTER’S STUDENTS OF PHARMACY. ACADEMIC STUDIES. SERIES “PEDAGOGY”, (3), 33–38. https://doi.org/10.52726/as.pedagogy/2025.3.5
ACM ACS APA ABNT Chicago Harvard IEEE MLA Turabian Vancouver

Download Citation

Endnote/Zotero/Mendeley (RIS) BibTeX

Abstract

This article analyzes the role of core chemical disciplines (general and inorganic chemistry, analytical chemistry, physical and colloidal chemistry) as fundamental elements in developing research competence among master’s students in pharmacy. Research competence is understood as a complex set of knowledge, skills, and abilities that include cognitive, procedural, and reflective components necessary for independent scientific research in the pharmaceutical field. Chemical education provides not only a deep understanding of molecular and physicochemical processes underlying pharmaceutical sciences but also fosters the development of methodological and practical skills essential for conducting precise, reliable, and reproducible experiments. General and inorganic chemistry form the cognitive foundation by developing analytical thinking, the ability to formulate hypotheses, and interpret experimental observations. Analytical chemistry contributes to enhancing procedural accuracy, teaching students to assess measurement uncertainty, validate methods and comply with quality standards, which are critical in professional pharmaceutical practice. Physical and colloidal chemistry develops skills in modeling, systems thinking, and integrating theoretical models with experimental data, enabling students to effectively plan and analyze complex chemical processes. Practice-oriented learning, including case studies, laboratory work and group discussions, stimulates the development of independence, critical thinking, teamwork skills, and promotes active knowledge acquisition through real-world application. Assessment encompasses both written reports and interactive sessions with active student participation, aimed at developing practical skills, understanding methodological aspects, and discussing potential problem situations. Special attention is given to the role of the instructor as a learning process facilitator, who supports students’ transition from acquiring theoretical knowledge to active research activity, provides motivation, mentorship and creates an atmosphere conducive to forming a research culture. Such an approach prepares future pharmacists capable of conducting independent scientific research and implementing results into professional practice.

https://doi.org/10.52726/as.pedagogy/2025.3.5
PDF

References

Agustian, H. Y., Pedersen, M. I., Finne, L. T., Jo̷rgensen, J. T., Nielsen, J. A., & Gammelgaard, B. (2022). Danish university faculty perspectives on student learning outcomes in the teaching laboratories of a pharmaceutical sciences education. Journal of Chemical Education, 99(11), 3633‒3643. https://doi.org/10.1021/acs.jchemed.2c00212.

Al-Thani, N. J., Saad, A., Siby, N., Bhadra, J., & Ahmad, Z. (2022). The role of multidisciplinary chemistry informal research programs in building research competencies and attitudes. Journal of Chemical Education, 99(5), 1957‒1970. https://doi.org/10.1021/acs.jchemed.2c00088.

Bain, K., Rodriguez, J. M. G., & Towns, M. H. (2019). Chemistry and mathematics: Research and frameworks to explore student reasoning. Journal of Chemical Education, 96(10), 2086‒2096. https://doi.org/10.1021/acs.jchemed.9b00523.

Fu, S., Wang, G., Xia, C., Li, H., & Zhang, H. (2021, March). Exploration and Practice of Blended Teaching of «Inorganic Chemistry». In 2021 9th International Conference on Information and Education Technology (ICIET) (pp. 145‒148). IEEE. https://doi.org/10.1109/ICIET51873.2021.9419639.

Gautam, K. K., & Agarwal, R. (2023). The new generation teacher: teacher as a facilitator. International Journal of Creative Research Thoughts, 11(7), 2320‒2882. https://doi.org/10.1729/Journal.35553.

Hardy, J. G., Sdepanian, S., Stowell, A. F., Aljohani, A. D., Allen, M. J., Anwar, A., ... & Wright, K. L. (2021). Potential for chemistry in multidisciplinary, interdisciplinary, and transdisciplinary teaching activities in higher education. Journal of Chemical Education, 98(4), 1124‒1145. https://doi.org/10.1021/acs.jchemed.0c01363.

Jørgensen, J. T. (2023). Longitudinal development of pharmaceutical students’ laboratory learning outcomes (Doctoral dissertation, Doctoral Thesis, Department of Science Education, University of Copenhagen).

Murry, L. T., Hughes, P. J., Singh, R. M., Travlos, D. V., & Engle, J. P. (2024). Current and future opportunities and challenges in continuing pharmacy education: a 2024 update. American Journal of Pharmaceutical Education, 88(10), 101281. https://doi.org/10.1016/j.ajpe.2024.101281.

Patel, P., & Thareja, P. (2024). Colloids and Interfaces: Where Science Meets Engineering, a Hands-on Learning Approach. Journal of Chemical Education, 101(5), 2072‒2079. https://doi.org/10.1021/acs.jchemed.3c01218.

Pazicni, S., & Popova, M. (2025). Making the Case for Inorganic Chemistry Education Research: Insights from Symmetry. Comments on Inorganic Chemistry, 1‒19. https://doi.org/10.1080/02603594.2025.2523259.

Poloyac, S. M., Empey, K. M., Rohan, L. C., Skledar, S. J., Empey, P. E., Nolin, T. D., ... & Kroboth, P. D. (2011). Core competencies for research training in the clinical pharmaceutical sciences. American journal of pharmaceutical education, 75(2), 27. https://doi.org/10.5688/ajpe75227.

Pushkarova, Y., Chkhalo, O., Reva, T., Zaitseva, G., & Bolotnikova, A. (2021). Using information technology in teaching of the course «Analytical Chemistry» in Bogomolets National Medical University. Archives of Pharmacy Practice, 12(3), 89‒93. https://doi.org/10.51847/dvMCSbO1SE.

Pushkarova, Y., & Zaitseva, G. (2022). Designing an online course for pharmacy students: Case study of basics of chemical metrology. Anatolian Journal of Education, 7(2), 1‒10. https://doi.org/10.29333/aje.2022.721a.

Roman, A. G. (2021). Research competencies and performance of higher education institutions (HEI) faculty. International Journal of research publications, 78(1), 37‒44. https://doi.org/10.47119/IJRP100781620211975.

Schnellert, L., Sinclair, K. A., & Butler, D. L. (2025). The role of the researcher-facilitator in professional learning networks. Journal of Professional Capital and Community. https://doi.org/10.1108/JPCC-10-2024-0177.

Winkelmann, K., Baloga, M., Marcinkowski, T., Giannoulis, C., Anquandah, G., & Cohen, P. (2015). Improving students’ inquiry skills and self-efficacy through research-inspired modules in the general chemistry laboratory. Journal of Chemical Education, 92(2), 247‒255. https://doi.org/10.1021/ed500218d.

Creative Commons License

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