International Journal of Animal and Veterinary Advances 1(1): 22-24, 2009ISSN: 2041-2908 M axwell Scientific Organization, 2009
Effect of Aqueous-ethanolic Stem Bark Extract of Commiphora Africana on Blood Glucose Levels on Normoglycemic Wistar Rats
1A.D .T.Goji, 2A.A .U. Dikko, 3A.G . Bakari, 1A. M ohamm ed, 1I. Ezekiel, and 1Y. Tanko
¹Departm ent of Hu man ph ysio logy , Ah madu B ello U nive rsity, Z aria, N igeria
2Department of Human physiology, Bayero University, Kano, Nigeria.
3Departm ent of Medicine, Ahmadu Bello University Teaching Hospital Shika, Nigeria
Abs tract: This study was undertaken to determine the hypog lycemic effec t of Comm iphora africana (family: Burseraceae) stem bark aqueous-ethanolic extract in normoglycemic W istar rats. In one set of experiment, graded doses of C. africana stem bark aqueous extract (100, 200 and 400 mg/kg p.o) were sepa rately administered to groups o f fasted norma l rats. The hypo glycem ic effect of C. africana stem bark aqueous ethan olic extrac t was com pared with th at of M etform in (250 mg/kg) in fasted norm al rats. Fo llowin g treatm ent, relatively mode rate to high dose s of C. africana (100, 200 and 400 mg /kg p.o ) produced a dos e-dep endent, significant reduc tion (p< 0.05) in blood glucose levels of fasted normal rats. Three doses of the extract (100, 200 and 400 mg/kg) were administered orally. A significant decrease in the blood glucose levels after 5 and 7 day of administration with the doses of 200 mg/k g and 400mg/k g w as ob serve d w hen com pared to contro l. As regard s to the dose of 100mg/kg there was no any significant decreased in the blood glucose levels when compared to con trol. The Preliminary phytochemical screening revealed the presence of alkaloids, tannins, flavonoids, steroids and saponins. The median lethal dose (LD ) in rats was calculated to be 3807.8 m g/kg
body we ight. In conclusio n the aque ous ethan olic extract of Comm iphora africanapossesses hypoglyc emicactivity in normoglycemic rats. Key w ords:Comm iphora african, hypoglycemic activity, phytochemicals. INTRODUCTON
scales; slas h red, p leasan tly scented, exuding
a clear gum. Has a creeping root system that spreads
Administration of various plant extract for the
several meters around the tree. Leaves trifoliate, leaflets
reduction of blood suga r levels of diabetics comprises an
cuneate at the base and with irregular and bluntly toothed
important aspect of the indigenous medicinal systems of
margins, waxy grey-green above with a sparse covering
many countries including Sri Lank a (Jayaw eera, 1982 ).
of hairs, lighter in color and more dens ely hairy below, up
Mo st of the plants prescribed for d ia be te s m ellitu s (D M )
to 4x2.5 cm, the middle leaflet larger than laterals.
are not edible (Atta-ur-Rahman and Zaman, 1989;
Flow ers in axillary clusters of 4-10; petals 4, red, not
Serasinghe et al., 1990) and th erefore the studies on
fused, but forming a tube about 6 mm long. Fruits reddish,
edible plants which have a hypoglycemic effect would be
6-8 mm acros s but so metim es larger, almost stalkless,
of great value in the dietary management of the disease.
made up of a tough outer layer, which splits when ripe to
The oral hypoglycemic activity of the stem bark of
reveal a hard, furrowed stone embedded in a red, resinous
comm iphora africana in normoglycemic healthy, Wistar
flesh. The generic name ‘Commiphora’ is based on the
Greek words ‘kommi’ (gum) and ‘phero’ (to bear). The
Com miphora africana belongs to the family of
spec ific nam e simp ly me ans A frican. T he ob jective o f this
Burseraceae and a group of plant called M yrrh (Hanus et
research work is to de termine the effect of aqueous
al., 2005; Dalziel and Hutchinson, 1956) and it is found
ethan olic stem b ark ex tract of commiphora africana on
on dry sites and savannah forest of Africa (Irvine, 196 1).
blood gluco se leve ls on no rmoglyce mic w istar rats. T his
It is traditionally used for the treatment of a number of
wo uld help in contributing toward ethno botanical uses of
ailment including the treatment of typhoid and wound
commiphora africana in Nigeria.
healing (Lew is and Elvin-Lew is, 197 7). Com miphoraafricana is a small tree, sometimes reaching 10 m but
MATERIALS AND METHODS
usua lly not m ore tha n 5 m high. It can be recognizedunm istakab ly from a distance by its outline-a spherical
Plan t M ateria l: The stem bark of commiphora africana
top and a short trunk with low branches. Crown is
was collected within Main campus, Ah mad u Bello
rounded, with the branches ascending and then curving
University, Zaria. The plant was identified and
downw ards. Many of the branchlets end in spines. The
authenticated by M. Musa of the herbarium section in
bark is grey-green, som etime s shiny , peeling in
the Depa rtment of Biolo gical Scien ce, A hma du B ello
Corresponding Author: A.D.T.Goji, Department of Human physiology, Ahmadu Bello University, Zaria, Nigeria Int. J. Anim. Veter. Adv., 1(1): 22-24, 2009
Effect of aqueo us ethanolic stem bark ex tract of commiphora africana on blood glucose levels of no rmoglycem ic Wistar rats.
-----------------------------------------------------------------------------------------------------------------------------------------Day 0
a = P< 0.05; a = significant, ns=not significant
Un iversity Zaria, where a herbarium specimen was
days after A lloxan injection , the blood glucos e leve ls was
prepared and deposited there with a voucher number
measured using the gluco se-ox idase princip le and only
those rats with fasting blood glucose g reater than 200mg/dL will be included in the study. (Stanley et al.,Extract Preparation: The stem bark of commiphora africana were collected and dried under shade and ground
The normoglyc emic rats were randomly assig ned into
into powder. The powder (500 g) was macerated in 30%
five groups (1-5) of six rats (n = 6) each as follows,
of distilled water and 7 0% ethanol at room temperature
for 24 hours. It was then filtered using a filtered paper(W hatm ann size no .1) and the filtrate ev aporated to
N ormal, treated W istar rats (were given
dryness in water bath at 60ºC. A brownish residue
No rmal sa line, 5 m l/kg bo dyw eight p .o
weighing 30.5 g was obtained. This was kept in air tight
Normal treated with 100 mg/kg extract p.o.
bottle in a refrigerator until used.
Normal, treated with 200 mg/kg extract p.o
No rmal, trea ted w ith 400 mg/k g extra ct p.o
Ch em icals used: All chemicals and drugs u sed w ere
No rmal, trea ted w ith metfo rmin (250 mg/kg
obtained commercially and of analytical grade.
p.o) (Marta et al., 2000: Solskov et al.,
A preliminary phytochemical screening of the stem
Determination of blood glucose levels: All blood sam ple
bark extract of comm iphora africana seed was also done
were collected from the tail artery of the rats at interval of
using standard methods of analysis (Trease and Evans,
0, 1, 3, 5 and 7 days. Determination of the blood glucose
levels was done by the glucose-oxidase principle (Beachand Turner,1958) using the ONE TOUCH B asic
Acu te toxicity study: LD determination was conducted
(Lifescan, MilpitasCA ) instrument and results were
using the method of Lorke (1983). In the initial phase,
expresse d as mg /dL (Rh eney an d Kirk, 20 00).
Albino Wistar rats were divided into three groups of threerats each. They were treated with the comm iphoraStatistical ana lysis: Blood glucose levels were expressed africana stem bark extract at doses of 100, 100 and 1000
in mg/d L as m ean ± SEM . The d ata w ere statistically
mg/kg per orally. Animals were observed for 24hours for
analyzed using ANOV A with multiple comparisons
any signs of toxicity. In the sec ond phas e of the toxicity
versus control group by Dunnett’s method. The values of
study the animal were grouped into three groups of one
p<0 .05 w ere tak en as significa nt.
rat each .Th ey w ere treated with the commiphora africana
Tab le 1. Effect of aq ueous eth anolic stem bark extract of
stem bark extract at doses of 1600, 2900 and 5000 mg/kg
commiphora africana on blood glucose levels of
per orally. Anim als were observed for 24 h and there was
Tab le 1 showed the results of the effect of three doses
Signs of the toxicity were first noticed after 5-8 h of
(100, 200 and 400 m g/kg) of aqu eous etha nolic stem ba rk
extract administration. There were decreased locomotor
extract of commiphora afriana, metformin and control
activity and sensitivity to touch. Also there was decreased
groups in normoglycemic Wistar rats. The dose of
feed intake, tachypnoea and prostration after 12 h of
metfo rmin and 100mg/kg of the extract did not show any
extract administration.The LD was calcu lated as 3807.8
significant change in blood glucose levels when comp ared
to the normal treated control group. However, the dosesof 200 and 400 mg/kg of the extract showed a significant
An ima ls used and experimental design: Thirty six
(p<0.05) decrease in the blood glucose levels after day 5
(36 ) Wister rats weighing between (120-150g) of about
20-25 weeks of age of both sexes was used and wasobtain from the Animal House of the Departmen t of
Pharmacology and Clinical Pharmacy, A.B.U. Zaria. Theywere kept in plastic cages under laboratory condition of
P hy to ch em ical screening: Resu lt of the preliminary
temperature and humidity and placed on standard feed
phytochemical screening o f comm iphora africana stem
and allow free access to wa ter with 12 h light/dark cycle.
bark extract revealed the presence of flavinoid s, tannin,
The animals w ere fasted for 12-18 h w ith free ac cess to
anthraquinone, cardiac glycosides alkaloids, triterpenoids,
water prior to the administration of the extract. Three
Int. J. Anim. Veter. Adv., 1(1): 22-24, 2009Acu te toxicity study: Signs of the toxicity were first
of Physio logy, F aculty of M edicin e Ahma du B ello
noticed after 5-8 hours of extract adm inistration. There
were decreased locomotor activity a nd se nsitivity totouch. Also there was decreased feed intake, tachypnoea
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ACKNOW LEDGMENTS
Trease, G.E. and M.S. Evans, 1989. Textbook of
The authors of this work wish to acknowledge the
Pharmacognosy. 14th Edn., B alliere T indall.,
technical assistance of Malam Y’au M . of the Department
Organisation du système nerveux central Rappel sur l’organisation microscopique : Elle concerne le tissu nerveux qui comporte deux grandes catégories de cellules : les cellules nerveuses (neurones, estimées à 100 milliards dans le cerveau) et la glie (cellules gliales, encore plus nombreuses) qui forment un réseau de tissu entre les neurones. Même si elles ne transmettent pas l’informa
Commonly Used Non-Opioid Analgesics Maximum Dose Average Dose y Used Non-Opioid Analgesics Side Effects Comments Interval Maximum Dose age Dose 4h 4 g (<3 g in Side Effects omments 5% with Interval patients with liv hepatic insufficiency or history of alcohol tion and in (<3 g in Minimal, if any, side effects abuse. Management th