| BMC Complement Altern Med. 2013 Jun 17;13:135. |
| Brine shrimp cytotoxicity of crude methanol extract and antispasmodic activity of α-amyrin acetate from Tylophora hirsuta wall.[Pubmed: 23773697 ] |
We have previously reported that aerial parts of Tylophora hirsuta have antispasmodic profile. The current work is an attempt for isolation of pharmacologically active compound(s) that contribute for its antispasmodic activity.
METHODS AND RESULTS:
Preliminary phytochemical screening for crude methanol extract of Tylophora hirsuta (Th.Cr) is performed. Brine shrimp cytotoxicity of crude methanol extract is performed. Column chromatography was used for isolation of compounds. Mass spectroscopy, H(1) NMR and C(13) NMR were used for structural determination of compounds. α-amyrin acetate was tried for possible spasmolytic activity in rabbit's jejunal preparations and KCl-induced contractions.
Th.Cr tested positive for saponins, alkaloids, flavonoids and terpenoids. Compound 1 was isolated as α-amyrin acetate. Compound 2 was heptaeicosanol. Crude methanol extract tested positive for brine shrimp cytotoxicity with LC(50) 492.33± 8.08 mg/ml. Compound 1 tested positive for antispasmodic activity on spontaneous rabbits' jejunum preparations with EC(50) (60 ± 2) × 10(-5)M. The compound also tested positive on KCl induced contractions with EC(50) (72 ± 3) × 10(-5)M.
CONCLUSIONS:
The present work confirms that α-amyrin acetate is has antispasmodic profile and the relaxant effect may be attributed to α-amyrin acetate which is a major compound. |
| Parasitol Res. 2012 Jun;110(6):2117-24. |
| Adult mortality and blood feeding behavioral effects of α-amyrin acetate, a novel bioactive compound on in vivo exposed females of Anopheles stephensi Liston (Diptera: Culicidae).[Pubmed: 22167372] |
The effect of alpha-Amyrin acetate on mortality and blood feeding behavior in females of Anopheles stephensi was assessed by in vivo exposure on treated guinea pig skin.
METHODS AND RESULTS:
In vivo exposure to alpha-Amyrin acetate caused mosquito knock down in the form of rapidly and normally reversible paralysis and the subsequent record at the end of a 24 h, revealed mortality rates of females increased from 0.0% (Control) to 76.9% at 1.6% alpha-Amyrin acetate, the highest concentration which implies the contact toxicity of the alpha-Amyrin acetate received through the sensitive parts of test species. The mean probing time responses significantly increased (P < 0.05) from 5.3 s (Control) to 22.9 s at 1.6% alpha-Amyrin acetate. The blood feeding rates and the mean engorgement times were significantly shorter when compared to the control. The mean blood feeding rates of exposed females decreased from 91.7% (control) to 41.5% at 0.8% alpha-Amyrin acetate concentrations, the mean engorgement time also decreased from 278.6 s (Control) to 158.7 s at 0.8% alpha-Amyrin acetate concentrations. Mean blood feeding rates and mean engorgement time were statistically significant (P < 0.05) from that of control. The mean fecundity levels significantly reduced from 96.2 (Control) to 65.95%. The shortened mean engorgement time and smaller blood meal size have played a more important role in decline of fecundity.
CONCLUSIONS:
In vivo exposure to alpha-Amyrin acetate caused increased mean probing time, decreased blood engorgement time and feeding rate and declined fecundity which reduce the overall survival and reproductive capacity of the malaria vector A. stephensi. |
| Nat Prod Res. 2009;23(9):876-82. |
| Antihyperglycaemic activity of alpha-amyrin acetate in rats and db/db mice.[Pubmed: 19488928] |
The article reveals the antihyperglycaemic activity of the alpha-Amyrin acetate (alpha-AA) isolated from the aerial roots of the Ficus bengalensis in normal and diabetic rats and model of type-2 diabetes, i.e. db/db mice.
METHODS AND RESULTS:
The oral administration of alpha-Amyrin acetate significantly improved the diabetic condition in streptozotocin-induced diabetic rats and in diabetic db/db mice at 50 mg kg(-1) dose level. |
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