249
Volume 5, Issue 10: Special Issue
(EJAR)
ISSN: 2181-2020
MPHAPP
THE 6TH INTERNATIONAL SCIENTIFIC AND PRACTICAL
CONFERENCE
“
MODERN PHARMACEUTICS: ACTUAL
PROBLEMS AND PROSPECTS
”
TASHKENT, OCTOBER 17, 2025
in-academy.uz
ON THE STUDY OF THE FLAVONOIDS OF LADIGINIA BUCHARICA LIPSKIYI
Komilov Kh.M.
Ikramova M.Sh.
Mukhitdinova M.K.
Tashkent Pharmaceutical Institute, Tashkent city, Republic of Uzbekistan
https://doi.org/10.5281/zenodo.17333616
Background
. Within the flora of Uzbekistan, many wild-growing plants remain insufficiently
and unevenly studied. Conducting in-depth pharmacognostic and pharmacological investigations and
introducing the results into medical practice are important tasks. One such plant is the Bukhara
Ladiginia. This species occurs in Central Asia (southern Pamir–Alay) and in Uzbekistan’s
Kashkadarya Region (Kaypantog‘lik area). Earlier, scientists of the Institute of the Chemistry of Plant
Substances, Academy of Sciences of Uzbekistan, in the Glycosides Laboratory (M. Pathullaeva, N.K.
Abubakirov), studied triterpene saponins from the underground parts of this plant. However, the
bioactive compounds of the aerial parts (flavonoids) have not been investigated.
Objective.
Ladiginia bucharica belongs to the genus Ladiginia of the family Apiaceae (celery
family), which in Uzbekistan comprises 73 genera and 203 species. It is a perennial plant 80–150 cm
tall. The study focused on the aerial parts (stems, leaves, and flowers), collected during flowering and
dried in the shade. The dried, crushed raw material was examined for flavonoids.
Preliminary paper chromatography was carried out after heating the material with 95% ethanol
in a water bath and filtering. The concentrate was developed in the system n-butanol–acetic acid–
water (5:1:4). After spraying with 3% ethanolic AlCl₃ and drying at 105 °C, spots characteristic of
flavonoids were observed under a UV lamp at Rf 0.46 and 0.94.
Materials and Methods.
To elucidate the chemical structures of the flavonoids, 1.0 kg of dried,
powdered raw material was extracted three times at room temperature with 95% ethanol. The
concentrated extract was diluted with water (1:2) and defatted/dechlorophyllized by five successive
extractions with 100 mL portions of extraction-grade petroleum ether, removing ballast substances
(chlorophyll). The purified aqueous phase was then extracted three times with 100 mL portions of n-
butanol. The combined butanolic fraction was evaporated in vacuo to yield 100 g of dry extract.
A capron (nylon) powder–packed chromatography column was loaded with 35.0 g of this
extract. The column was eluted first with water and then with 5%, 10%, and 20% aqueous ethanol.
Fractions (150 mL each) were collected. The presence of flavonoids in fractions was monitored by
spotting on filter paper, spraying with 3% ethanolic AlCl₃, heating, and examining under UV light.
Results.
Fractions displaying flavonoid-characteristic spots were evaporated in a water-bath
under reduced pressure; some were further purified by rechromatography. Two compounds were
isolated:
• Substance A: m.p. 278–279 °C; formula C₁₅H₁₀O₆; M⁺ 286; Rf 0.94 in n-butanol–acetic acid–
water (5:1:4). Identification was performed using the reference compound kaempferol and by
comparing mass and UV spectra.
• Substance B: m.p. 316–317 °C; formula C₁₅H₁₀O₇; M⁺ 302; Rf 0.46. Identification was carried
out with the reference compound quercetin, also by comparison of mass and UV spectra.
Kaempferol and quercetin were thus isolated from Ladiginia bucharica Lipskiyi and identified
for the first time.
250
Volume 5, Issue 10: Special Issue
(EJAR)
ISSN: 2181-2020
MPHAPP
THE 6TH INTERNATIONAL SCIENTIFIC AND PRACTICAL
CONFERENCE
“
MODERN PHARMACEUTICS: ACTUAL
PROBLEMS AND PROSPECTS
”
TASHKENT, OCTOBER 17, 2025
in-academy.uz
Conclusion.
The aerial parts of this wild-growing plant widespread in Uzbekistan contain the
flavonoids kaempferol and quercetin. Further work will continue on comprehensive investigation of
its bioactive constituents and on evaluating their biological activities.
