THERMAL SCIENCE

International Scientific Journal

Han Yang

,

Shuaiwei Dong

,

Zhiyong Sun

,

Yaoming Wang

,

Xuefeng Luo

,

Bo Chen

,

Guanzhong Yao

,

Yang Gao

,

Chunxia Lv

,

Dongfang Zheng

,

Yong Zhao

,

Ting Wang

,

Shuangxi Yan

,

Wanxi Peng

CATALPA OVATA G. DON. POTENTIAL MEDICINAL VALUE OF LEAVES

ABSTRACT
Catalpa ovata G. Don. has a certain degree of appreciation because of its unique tree shape and wide crown. It also has certain adaptability. This experiment uses organic materials such as Fourier transform infrared (FT-IR) spectroscopy, gas chromatography-mass spectrometer (GC-MS), learning content management system, thermal desorption - GC-MS, termal gravimetric analyzer and other modern techniques to extract organic reagents from Catalpa ovata G. Don’s Leaves. The original powder was tested differently and analyzed, investigated. To explored and developed its potential medicinal value, and better understood its use in biomedicine, as well as perfumery and chemical industries, providing some research for further and in-depth research basis.
KEYWORDS
Catalpa ovata G. Don. Leaves QTOF-LCMS Biomedicine Spices
PAPER SUBMITTED: 2019-06-09
PAPER REVISED: 2019-08-26
PAPER ACCEPTED: 2019-09-06
PUBLISHED ONLINE: 2020-02-08
DOI REFERENCE: https://doi.org/10.2298/TSCI190609043Y
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2020, VOLUME 24, ISSUE Issue 3, PAGES [1713 - 1720]
REFERENCES
  1. Pae, H. O., et al., Inhibitory effects of the stem bark of Catalpa ovata G. Don.(Bignoniaceae) on the productions of tumor necrosis factor-α and nitric oxide by the lipopolisaccharide-stimulated RAW 264.7 macrophages, Journal of ethnopharmacology, 88 (2003), 2-3, pp. 287-291
  2. Machida, K., et al., Studies on the Constituents of Catalpa Species. IX. Iridoids from the Fallen Leaves of Catalpa ovata G. D ON. Chemical and pharmaceutical bulletin, 52 (2004), 5, pp. 618-621
  3. Park, S., et al,. Characterization of inhibitory constituents of NO production from Catalpa ovata using LC-MS coupled with a cell-based assay, Bioorganic chemistry, 80 (2018), pp. 57-63
  4. GONG, Y. T., et al., Study on Extraction Technology of Flavonoids from Fruit of Catalpa Ovata G. Don., Food Science, 4 (2008)
  5. Oh, H., et al., Inhibition of inducible nitric oxide synthesis by catalposide from Catalpa ovata. Planta medica, 68 (2002), 08, pp. 685-689
  6. Park, B. M., et al., Naphthoquinones from Catalpa ovata and their inhibitory effects on the production of nitric oxide. Archives of pharmacal research, 33 (2010), 3, pp. 381-385
  7. Jianhua, L. I., Phylogeny of Catalpa (Bignoniaceae) inferred from sequences of chloroplast ndhF and nuclear ribosomal DNA. Journal of Systematics and Evolution, 46 (2008), 3, pp. 341-348
  8. Petit, T., and Ljiljana P. FTIR spectroscopy of nanodiamonds: Methods and interpretation, Diamond and Related Materials, (2018)
  9. Müsellim, E., et al., Thermokinetic and TG/DSC-FTIR study of pea waste biomass pyrolysis, Applied Thermal Engineering, 137 (2018), pp. 54-61
  10. Blaženović, I., et al., Software tools and approaches for compound identification of LC-MS/MS data in metabolomics, Metabolites, 8 (2018), 2, pp. 31
  11. Banerjee, S., et al., LC-MS/MS analysis and Network Pharmacology of Trigonella foenum-graecum-a plant from Ayurveda against Hyperlipidemia and Hyperglycemia with combination synergy, Phytomedicine, (2019), pp. 152944
  12. Sivapalan, T., et al., An LC-MS/MS Method to Measure S-Methyl-l-Cysteine and S-Methyl-l-Cysteine Sulfoxide in Human Specimens Using Isotope Labelled Internal Standards. Molecules, 24 (2019), 13, pp. 2427
  13. Chen, J. T., GC-MS explores the health care components in the extract of Pterocarpus pedatus Pierre, Saudi Journal of Biological Sciences, 25 (2018), pp. 1183-1188
  14. Ge, S. B., et al., Biological analysis on extractives of bayberry fresh flesh by GC-MS, Saudi Journal of Biological Sciences, 36 (2018), 14, pp. 816-818
  15. Klein, D., et al., Detection of volatile organic compounds arising from chicken breast filets under modified atmosphere packaging using TD-GC/MS, Food analytical methods, 11 (2018), 1, pp. 88-98
  16. Xu, L., et al., Non-Isothermal Combustion Properties of Plant Biomaterial Using TG-DSC Technique, Defect and Diffusion Forum, Trans Tech Publications, 2018, pp. 382
  17. Zhao, J. C., et al., Studies on the Thermal Behaviors of Hexogen, Ammonium Perchlorate and Their Mixtures by TG-DSC, DEStech Transactions on Environment, Energy and Earth Sciences, icner (2018)
  18. Ihalainen, J. A., et al., Chromophore-protein interplay during the phytochrome photocycle revealed by step-scan FTIR spectroscopy. Journal of the American Chemical Society, 140 (2018), 39, pp. 12396-12404
  19. Chen, L., et al., Measurement and characterization of external oil in the fried waxy maize starch granules using ATR-FTIR and XRD. Food chemistry, 242 (2018), pp. 131-138
  20. Shi, T., et al., FTIR study on early-age hydration of carbon nanotubes-modified cement-based materials. Advances in Cement Research, (2018), pp. 1-9
  21. Spiandore, M., et al., Desorption of sulphur mustard simulants methyl salicylate and 2-chloroethyl ethyl sulphide from contaminated scalp hair after vapour exposure. Chemosphere, 191 (2018), pp. 721-728
  22. Kumar, T. E., et al., Synthesis of salicylate esters over cordierite honeycomb monoliths coated with zirconia based solid acids in vapour phase, (2018)
  23. Sumangala, H. P., et al., High concrete and ester containing Jasmine species (Jasminum malabaricum Wight). IJCS, 6 (2018), 2, pp. 3008-3013
  24. Jovanovich, A., et al., Deoxycholic acid, a metabolite of circulating bile acids, and coronary artery vascular calcification in CKD, American Journal of Kidney Diseases, 71 (2018), 1, pp. 27-34
  25. Esteban, M., et al., Bifurcation analysis of hysteretic systems with saddle dynamics. Applied Mathematics & Nonlinear Sciences, 2 (2017), 2, pp. 449-464
  26. Lokesha, V., et al., Reckoning of the dissimilar topological indices of human liver. Applied Mathematics & Nonlinear Sciences, 3 (2018), 1, pp. 265-276
  27. Patel, J., et al., Recurrent Xanthelasmas Treated With Intralesional Deoxycholic Acid. Dermatologic Surgery (2019)
  28. Berwal, R., et al., Investigation on Biomolecules in Ethanol Extract of Fruits of Prosopis Juliflora (Sw.) DC. Using GC-MS, Journal of Herbs, Spices & Medicinal Plants, 25 (2019), 2, pp. 172-180
  29. De Roos, J., and Luc D. V., Acetic acid bacteria in fermented foods and beverages. Current opinion in biotechnology, 49 (2018), pp. 115-119
  30. Gutbrod, K., et al., Phytol metabolism in plants. Progress in lipid research, (2019)
  31. Zheng, H. D., et al., Continuous synthesis of isobornyl acetate catalyzed by a strong acid cation exchange resin in an oscillatory flow reactor. Chemical Engineering and Processing-Process Intensification, 134 (2018), pp. 1-8
  32. Peng, W. X., Molecules and functions of Cornus officinalis bark volatiles. Emirates Journal of Food and Agriculture, (2018), pp. 828-838
  33. Chen, J. T., et al., Molecules and Functions of Rosewood: Diospyros celebica, Arabian Journal of Chemistry, 11 (2018), pp. 756-762
  34. Xu, Y. Q., et al., Effect of lignin, cellulose and hemicellulose on calcium looping behavior of CaO-based sorbents derived from extrusion-spherization method, Chemical Engineering Journal, 334 (2018), pp. 2520-2529
  35. Bawareth, B., et al., Electrochemical Membrane Reactor Modeling for Lignin Depolymerization, ACS Sustainable Chemistry & Engineering, 7 (2018), 2, pp. 2091-2099
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Catalpa ovata G. Don. potential medicinal value of leaves

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