Effect of Bidens tripartita leaf supplementation on the organism of rats fed a hypercaloric diet high in fat and fructose

Alakbarov, F. U. (2001). Medicinal plants used in medieval Azerbaijan phytotherapy. Journal of Herbal Pharmacotherapy, 1(3), 35–49.

Alarcon-Aguilar, F. J., Roman-Ramos, R., Flores-Saenz, J. L., & Aguirre-Garcia, F. (2002). Investigation on the hypoglycaemic effects of extracts of four Mexican medicinal plants in normal and Alloxan-diabetic mice. Phytotherapy Research, 16(4), 383–386.

Chang, S.-L., Chang, C. L.-T., Chiang, Y.-M., Hsieh, R.-H., Tzeng, C.-R., Wu, T.-K., Sytwu, H.-K., Shyur, L.-F., & Yang, W.-C. (2004). Polyacetylenic compounds and butanol fraction from Bidens pilosa can modulate the differentiation of helper T cells and prevent autoimmune diabetes in non-obese diabetic mice. Planta Medica, 70(11), 1045–1051.

Chang, C. L.-T., Kuo, H.-K., Chang, S.-L., Chiang, Y.-M., Lee, T.-H., Wu, W.-M., Shyur, L.-F., & Yang, W.-C. (2005). The distinct effects of a butanol fraction of Bidens pilosa plant extract on the development of Th1-mediated diabetes and Th2-mediated airway inflammation in mice. Journal of Biomedical Science, 12(1), 79–89.

Chien, S.-C., Young, P. H., Hsu, Y.-J., Chen, C.-H., Tien, Y.-J., Shiu, S.-Y., Li, T.-H., Yang, C.-W., Marimuthu, P., Tsai, L. F.-L., & Yang, W.-C. (2009). Anti-diabetic properties of three common Bidens pilosa variants in Taiwan. Phytochemistry, 70(10), 1246–1254.

Donchenko, L. V., Limareva, N. S., Temnikov, A. V., Sokol, N. V., & Gorlov, S. M. (2021). Food pectin-containing phytocompositions as the basis of functional herbal teas. IOP Conference Series: Earth and Environmental Science, 677(3), 032037.

Kaškonienė, V., Kaškonas, P., Maruška, A., & Ragažinskienė, O. (2011). Chemical composition and chemometric analysis of essential oils variation of Bidens tripartita L. during vegetation stages. Acta Physiologiae Plantarum, 33(6), 2377–2385.

Kaškonienė, V., Kaškonas, P., Maruška, A., & Ragažinskienė, O. (2013). Essential oils of Bidens tripartita L. collected during period of 3 years composition variation analysis. Acta Physiologiae Plantarum, 35(4), 1171–1178.

Kaškoniene, V., & Maruška, A. (2015). Investigation of recovery of volatiles of Bidens tripartita L. using solid-phase extraction trap in supercritical fluid extraction. Acta Chimica Slovenica, 62(1), 1–7.

Karazhan, N. V., Yanchanka, V. V., & Buzuk, G. N. (2014). Vliyanye flavonoidov i polisakharidov cheredy trekhrazdelnoy na stabilizatsiyu tuchnykh kletok in vitro [Influence of flavonoids and polysaccharides of bur-marigold on stabilizing mast cells in vitro]. Vestnik Farmacii, 65, 100–104 (in Russian).

Karazhan, N. V., & Buzuk, G. N. (2015). Antianaphylactic activity of infusions of bur-marigold herb species and antiallergic collection. Vestnik Farmacii, 68, 57–61.

Khatamov, K., Suyarov, A., Ziyadullaev, S., Kireev, V., & Mukhtorov, S. (2020). Specific activity of a new antiallergic ointment in the treatment of contact allergic dermatitis. International Journal of Pharmaceutical Research, 12(2), 211–214.

Kotov, S., Kotova, E., Bezruk, I., Gontova, T., & Kotov, A. (2020). The study of the extraction dynamics of biologically active substances from the Bidens tripartita L. herb and antioxidant activity of the obtained extracts. Eureka: Health Sciences, 6, 95–101.

Lieshchova, M. A., Bohomaz, A. A., & Brygadyrenko, V. V. (2021). Effect of Salvia officinalis and S. sclarea on rats with a high-fat hypercaloric diet. Regulatory Mechanisms in Biosystems, 12(3), 554–563.

Lieshchova, M. A., & Brygadyrenko, V. V. (2021). Influence of Lavandula angustifolia, Melissa officinalis and Vitex angus-castus on the organism of rats fed with excessive fat-containing diet. Regulatory Mechanisms in Biosystems, 12(1), 169–180.

Lieshchova, M., & Brygadyrenko, V. (2022). Effects of Origanum vulgare and Scutellaria baicalensis on the physiological activity and biochemical parameters of the blood in rats on a high-fat diet. Scientia Pharmaceutica, 90(3), 49.

Lieshchova, M., Yefimov, V., & Brygadyrenko, V. (2023c). Influence of Inula helenium rhizomes and Matricaria chamomilla inflorescences on the biochemical and physiological parameters in male rats fed a high-fat diet. Roczniki Państwowego Zakładu Higieny, 74(4), 447–458.

Lieshchova, M., & Brygadyrenko, V. (2023a). Effect of Rhodiola rosea Rhizomes and Punica granatum fruit peel on the metabolic processes and physiological activity of rats fed with excessive fat diet. Food Technology and Biotechnology, 61(2), 202–211.

Lieshchova, M. A., & Brygadyrenko, V. V. (2023b). Effect of Echinacea purpurea and Silybum marianum seeds on the body of rats with an excessive fat diet. Biosystems Diversity, 31(1), 90–99.

Lieshchova, M. A., & Brygadyrenko, V. V. (2023c). The effect on the organism of rats of adding Helichrysum arenarium inflorescences to a hypercaloric diet, high in sugar and fat. Biosystems Diversity, 31(3), 350–357.

Lopes, D. C. D. X. P., De Oliveira, T. B., Viçosa, A. L., Valverde, S. S., & Ricci Júnior, E. (2021). Anti-inflammatory activity of the compositae family and it’s therapeutic potential. Planta Medica, 87, 71–100.

Lupuşoru, R. V., Mititelu-Tarţău, L., Sandu, R. B., Popa, G., Zagnat, M., & Lupuşoru, C. E. (2016). Experimental investigations on the effects of Bidens tripartita extracts in nociceptive reactivity. Farmacia, 64(1), 100–103.

Lupuşoru, C. E., Popa, E. G., Sandu, R. B., Buca, B. R., Mititelu-Tarţău, L., & Lupuşoru, R. V. (2017). The influence of Bidens tripartita extracts on psychomotor abilities and cognitive functions in rats. Farmacia, 65(2), 284–288.

Mendel, M., Chłopecka, M., Latek, U., Karlik, W., Tomczykowa, M., Strawa, J., & Tomczyk, M. (2020). Evaluation of the effects of Bidens tripartita extracts and their main constituents on intestinal motility – An ex vivo study. Journal of Ethnopharmacology, 259, 112982.

Nurzhanova, F., Absatirov, G., Sidikhov, B., Sidorchuk, A., Ginayatov, N., & Murzabaev, K. (2021). The vulnerary potential of botanical medicines in the treatment of bacterial pathologies in fish. Veterinary World, 14(3), 551–557.

Orhan, N., İçöz, Ü. G., Altun, L., & Aslan, M. (2016). Anti-hyperglycaemic and antioxidant effects of Bidens tripartita and quantitative analysis on its active principles. Iranian Journal of Basic Medical Sciences, 19(10), 1114–1124.

Oproshanska, T., Mishchenko, O., Shapoval, O., Khvorost, O., Koiro, O., & Bondariev, Y. (2021). Study of membrane-stabilizing and anti-inflammatory activity of tincture from herba Bidens tripartita L. Pharmacology Online, 3, 1863–1869.

Oproshanskaya, T. V. (2015). Fatty acids from Bidens tripartita Herb. Chemistry of Natural Compounds, 51(5), 944–945.

The State Pharmacopoeia of Ukraine (2018). 2nd ed. suppl. 2. Ukrainian Scientific Pharmacopoeial Center for Quality of Medicines, Kharkiv.

Serbin, A. G., Borisov, M. I., Chernobai, V. T., Kovalev, I. P., & Gordienko, V. G. (1975). Flavonoids of Bidens tripartita. III. Chemistry of Natural Compounds, 11(2), 160–162.

Szekalska, M., Sosnowska, K., Tomczykowa, M., Winnicka, K., Kasacka, I., & Tomczyk, M. (2020). In vivo anti-inflammatory and anti-allergic activities of cynaroside evaluated by using hydrogel formulations. Biomedicine and Pharmacotherapy, 121, 109681.

Sandu, R. B., Tarţǎu, L., Miron, A., Zagnat, M., Ghiciuc, C. M., & Lupuşoru, C. E. (2012). Experimental researches on acute toxicity of a Bidens tripartita extract in mice – preliminary investigations. Revista Medico-Chirurgicalǎ̌ a Societǎ̌ţii de Medici ş̧i Naturaliş̧ti din Iaş̧i, 116(4), 1230–1234.

Sandu, R. B., Tarţǎu, L., Miron, A., Zagnat, M., Ghiciuc, C. M., & Lupuşoru, C. E. (2013). In vivo biocompatibility evaluation of some Bidens tripartita extracts in rats. Revista Medico-Chirurgicalǎ̌ a Societǎ̌ţii de Medici ş̧i Naturaliş̧ti din Iaş̧i, 117(3), 795–800.

Shayakhmetova, G. M., Kovalenko, V. M., Basovska, O. G., & Vozna, A. V. (2020). Clinical biochemical parameters of healthy adult white male rats blood serum (retrospective assessment). Pharmacology and Drug Toxicology, 13(6), 428–433.

Singh, G., Passsari, A. K., Singh, P., Leo, V. V., Subbarayan, S., Kumar, B., Singh, B. P., Lalhlenmawia, H., & Kumar, N. S. (2017). Pharmacological potential of Bidens pilosa L. and determination of bioactive compounds using UHPLC-QqQLIT-MS/MS and GC/MS. BMC Complementary and Alternative Medicine, 17(1), 492.

Śliwa, P., Śliwa, K., Sikora, E., Ogonowski, J., Oszmiański, J., & Nowicka, P. (2019). Incorporation of bioflavonoids from Bidens tripartita into micelles of non-ionic surfactants – experimental and theoretical studies. Colloids and Surfaces B: Biointerfaces, 184, 110553.

Tomczykowa, M., Gudej, J., Majda, T., & Góra, J. (2005). Essential oils of Bidens tripartita L. Journal of Essential Oil Research, 17(6), 632–635.

Tomczykowa, M., Wróblewska, M., Winnicka, K., Wieczorek, P., Majewski, P., Celińska-Janowicz, K., Sawczuk, R., Miltyk, W., Tryniszewska, E., & Tomczyk, M. (2018). Novel gel formulations as topical carriers for the essential oil of Bidens tripartita for the treatment of candidiasis. Molecules, 23(10), 2517.

Uysal, S., Ugurlu, A., Zengin, G., Baloglu, M. C., Altunoglu, Y. C., Mollica, A., Custodio, L., Neng, N. R., Nogueira, J. M. F., & Mahomoodally, M. F. (2018). Novel in vitro and in silico insights of the multi-biological activities and chemical composition of Bidens tripartita L. Food and Chemical Toxicology, 111, 525–536.

Wolniak, M., Tomczykowa, M., Tomczyk, M., Gudej, J., & Wawer, I. (2007). Antioxidant activity of extracts and flavonoids from Bidens tripartita. Acta Poloniae Pharmaceutica – Drug Research, 64(5), 441–447.

Wahyuddin, M., Nurdaonah, N., & Ferawati, F. (2020). Activity of Bidens pilosa herb infussion as antiinflammatory. Ad-Dawaa’ Journal of Pharmaceutical Sciences, 3(1), 66–71.

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