Scabiosa Genus: A Rich Source of Bioactive Metabolites
Abstract
:1. Introduction
2. Scabiosa Genus: Traditional and Pharmacological Applications
3. Structural Pattern of the Secondary Metabolites Isolated from Scabiosa Species
4. In Vivo Assessments of Nominated Metabolites
4.1. Flavonoid-Type Metabolites
4.2. Iridoid Type Metabolites
4.3. Pentacyclic Triterpenoid Type Metabolites
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Nº | Name 1 | Plant Part (Solvent) | Species |
---|---|---|---|
Flavonoid Derivatives | |||
1 | Apigenin a | Whole plant (MeOH) [28] Whole plant (EtOH) [29] | S. tenuis [28] S. stellata [29] |
2 | Astragallin b | Flowering plants (CH2Cl2/MeOH) [23] | S. hymettia [23] |
3 | Cynaroside b | Whole plant (MeOH or ButOH) [28] Aerial (leaves and stems) parts (EtOH) [22] Epigeal part (MeOH) [30] | S. atropurpurea [22] S. olgae [30] S. tenuis [28] S. argentea [28] |
4 | Diosmetin-7-O-β-glucoside b | Whole plant (ButOH) [28] | S. argentea [28] |
5 | Hyperin 3,b | Whole plant (EtOH) [2] | S. stellata [2] |
6 | Isoorientin b | Whole plant (EtOH) [2,29] Whole plant (ButOH) [28] | S. argentea [28] S. stellata [2,29] |
7 | Isovitexin b | Whole plant (MeOH) [28] | S. tenuis [28] |
8 | Kaempferol-3-O-[3-O-acetyl-6-O-(E)-p-coumaroyl]-β-d-glucoside b | Flowering plants (CH2Cl2/MeOH) [23] Whole plant (EtOH) [31] | S. hymettia [23] S. stellata [31] |
9 | Lucenin 2,b | Whole plant (EtOH) [29] | S. stellata [29] |
10 | Luteolin a | Aerial (leaves and stems) parts (EtOH) [22] Whole plant (EtOH) [29] Whole plant (MeOH) [28] | S. atropurpurea [22] S. tenuis [28] S. stellata [29] |
11 | Luteolin-7-O-β-gentiobioside c | Whole plant (MeOH or ButOH) [28] | S. argentea [28] S. tenuis [28] |
12 | Luteolin-7-O-rutinoside c | Aerial (leaves and stems) parts (EtOH) [22] | S. atropurpurea [22] |
13 | Quercetin a | Whole plant (ButOH) [28] | S. argentea [28] |
14 | Quercetin-3-O-arabinoside b | Whole plant (ButOH) [28] | S. argentea [28] |
15 | Quercetin-3-O-galactoside b | Whole plant (ButOH) [28] | S. argentea [28] |
16 | Swertiajaponin b | Whole plant (EtOH) [2] | S. stellata [2] |
17 | Tamarixetin 3-β-l-rhamnosyl-(1→2)[β-l-rhamnosyl-(1→6)]β-d-glucoside] d | Whole plant (EtOH) [29] | S. stellata [29] |
18 | Tiliroside b | Whole plant (EtOH) [29] | S. stellata [29] |
19 | Vitexin b | Whole plant (MeOH) [28] | S. tenuis [28] |
Terpenoid derivatives | |||
20 | 7-O-(E-Caffeoyl)sylvestroside I c | Whole plant (EtOH) [2] | S. stellata [2] |
21 | 7-O-(E-p-Coumaroyl)sylvestroside I c | Whole plant (EtOH) [2] | S. stellata [2] |
22 | Cantleyoside c | Flowers (MeOH) [32] Whole plant (MeOH) [33] | S. atropurpurea [32] S. variifolia [33] |
23 | Eustomoruside b | Whole plant (EtOH) [2] | S. stellata [2] |
24 | Eustomoside b | Whole plant (EtOH) [2] | S. stellata [2] |
25,26 | Hookeroside A g and B h | Whole plant (MeOH) [34] | S. tschilliensis [34] |
27 | Loganic acid b | Flowering plants (CH2Cl2/MeOH) [23] Flowers (MeOH) [32] Whole plant (MeOH) [33] | S. hymettia [23] S. atropurpurea [32] S. variifolia [33] |
28 | Loganin b | Flowering plants (CH2Cl2/MeOH) [23] Flowers (MeOH) [32] Whole plant (MeOH) [33] | S. hymettia [23] S. atropurpurea [32] S. variifolia [33] |
29 | Palustroside III d | Whole plant (EtOH) [31] | S. stellata [31] |
30 to 40 | Scabiosaponin A g, B h, C h, D f, E f, F f, G g, H g, I f, J f and K g | Whole plant (MeOH) [34] | S. tschilliensis [34] |
41 to 48 | Scabiostellatosides A g, B g, C h, D h, E h, F h, G e and H d | Whole plant (EtOH) [31] | S. stellata [31] |
49 to 52 | Scabrioside A d, B e, C e, and D f | Roots (MeOH) [35] | S. rotata [35] |
53 | Septemfidoside c | Whole plant (EtOH) [2] | S. stellata [2] |
54 to 60 | Songoroside A b, C c, E d, G e, I f, M g and O h | Roots (EtOH) [36] | S. songarica2 [36] |
61 | Stigmasterol a | Whole plant (hexane) [37] | S. stellata [37] |
62 | Sweroside b | Whole plant (EtOH) [2] Flowers (MeOH) [32] Whole plant (MeOH) [33] | S. atropurpurea [32] S. variifolia [33] S. stellata [2] |
63 | Swertiamarin b | Flowering plants (CH2Cl2/MeOH) [23] Flowers (MeOH) [32] Whole plant (MeOH) [33] | S. hymettia [23] S. atropurpurea [32] S. variifolia [33] |
64 | Sylvestroside I c | Whole plant (EtOH) [2] | S. stellata [2] |
65 | Ursolic acid a | Whole plant (EtOH) [31] Whole plant (hexane) [37] | S. stellata [32,37] |
66 | β-Sitosterol-β-d-glucoside b | Whole plant (hexane) [37] | S. stellata [37] |
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Pinto, D.C.G.A.; Rahmouni, N.; Beghidja, N.; Silva, A.M.S. Scabiosa Genus: A Rich Source of Bioactive Metabolites. Medicines 2018, 5, 110. https://doi.org/10.3390/medicines5040110
Pinto DCGA, Rahmouni N, Beghidja N, Silva AMS. Scabiosa Genus: A Rich Source of Bioactive Metabolites. Medicines. 2018; 5(4):110. https://doi.org/10.3390/medicines5040110
Chicago/Turabian StylePinto, Diana C. G. A., Naima Rahmouni, Noureddine Beghidja, and Artur M. S. Silva. 2018. "Scabiosa Genus: A Rich Source of Bioactive Metabolites" Medicines 5, no. 4: 110. https://doi.org/10.3390/medicines5040110
APA StylePinto, D. C. G. A., Rahmouni, N., Beghidja, N., & Silva, A. M. S. (2018). Scabiosa Genus: A Rich Source of Bioactive Metabolites. Medicines, 5(4), 110. https://doi.org/10.3390/medicines5040110