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131

*Edo State School of Health
Technology, Benin City, Nigeria
**Department of Medical Laboratory
Science, School of Basic Medical
Science, College of Medical Sciences,
University of Benin, Nigeria

Correspondence:
Dr. (Mrs.) E. O. Osime
Department of Medical Laboratory
Science
School of Basic Medical Science
College of Medical Sciences
University of Benin, Nigeria
Email: evarista.osime@uniben.edu
ORCID ID: https://orcid.org/0000-
0003-4972-9735

Date of first submission, November 21,
2 01 8
Date of final revised submission, July 2,
2 01 9
Date of acceptance, July 10, 2019

This open access article is distributed
under a Creative Commons Attribution-
Non Commercial-Share Alike 4.0
International License

ABSTRACT

UNIVERSA MEDICINA

Haemostatic properties of Vernonia amygdalina and
Chromolaena odorata leaf extracts using Wistar rat model

Lucy Omokhegbe Matthew* and Evarista Odaburhine Osime**

BACKGROUND
The leaves of African plants are widely employed in Nigeria to control
bleeding from wounds. This work is aimed at evaluating the haemostatic
effects of Vernonia amygdalina (VA/bitter leaf) and Chromolaena odorata
(CO/sunflower) leaves on some haemostatic parameters.

METHODS
A laboratory study of experimental design was conducted involving 35
Wistar rats that were randomized into seven groups. Groups 1 and 2 received
leaf extracts of VA at concentrations of 150 and 250mg/kg BW, respectively;
groups 3 and 4 received leaf extracts of CO at 150 and 250mg/kg BW;
groups 5 and 6 received combined leaf extracts of VA and CO at 150 and
250mg/kg BW, respectively, for 30 days. The last group 7 as control group
received only water. Parameters investigated were clotting time (CT),
fibrinogen concentration, prothrombin time (PT), activated partial
thromboplastin time test (APTT), factor VII, protein C and D – dimer.

RESULTS
There was a significant reduction in CT, fibrinogen concentration and PT
in the intervention groups compared to controls (p<0.01). There was no
significant difference in APTT, factor VII and protein C in the intervention
groups compared to the controls (p>0.05). D-dimer levels were observed to
increase significantly in rats treated with 150mg/kg BW of VA and 150mg/
kgBW of the combined leaf extracts (VA/CO) compared to the controls
(p<0.05).

CONCLUSION
The VA and CO extracts reduced CT, PT, fibrinogen concentrations and
increased D-dimer levels in rats. This study suggests the possible
incorporation of the leave extracts of VA and CO in bleeding diathesis as
well as in coagulation studies.

Keywords: Haemostatic parameter, Vernonia amygdalina, Chromolaena
odorata, rats

ORIGINAL ARTICLE
pISSN: 1907-3062 / eISSN: 2407-2230

DOI: http://dx.doi.org/10.18051/UnivMed.2019.v38.131-138

May-August, 2019                                                                                                              Vol.38- No.2

Cite this article as: Matthew LO, Osime
EO. Haemostatic properties of Ver-
nonia amygdalina and Chromolaena
odorata leaf extracts using Wistar rat
model. Univ Med 2019;38:131-8. doi:
1 0 . 1 8 0 5 1 / Un i vM ed . 2 0 1 9 . v 3 8 . 1 3 1 -
1 3 8



132

Matthew, Osime                                                                         Vernonia amygdalina and Chromolaena odorata on haemostasis

INTRODUCTION

Whenever blood vessels are damaged, there
is an immediate physiological response designed
to minimize and arrest blood loss.(1) The sum total
of this response is encompassed by the term
haemostasis and involves the interaction of the
vascular system, platelets, plasma proteins,
inhibitors and the fibrinolytic system.(2) The
functions of these components are divided into
primary and secondary haemostatic mechanisms.
The primary haemostatic mechanism involves the
vascular system and platelets, while the secondary
mechanism involves the plasma protein responses
of the coagulation process to injury. The combined
eff ects of  these mec hanisms lead to the
formation of a stable fibrin-platelet plug, vessel
healing and dissolution of the plug.(3)

Vernonia amygdalina (VA) commonly
called bitter leaf is a perennial shrub, 2.5m in height,
that grows throughout tropical Africa.(4) It belongs
to the family Asteraceae and has elliptic leaves
that are about 6mm in length. The leaves are green
and have a characteristics odor and bitter taste.(5)

The macerated leaves of the plant are consumed
as vegetables and condiments and a source of
green leafy vegetable for culinary application as
well as for topical treatment of wounds.(6) In
many parts of Nigeria the plant has been
domesticated.(7) Different ethnic groups in
Nigeria ascribe various names to this plant such
as Ewuro, Etidot, Onugbu, Chusa-dike, “Ebe-
Oriwo” and others.(8)

Chromolaena odorata (CO) is a tropical
species of flowering shrub in the sunflower family
Asteraceae. In Western Africa, it prevents
regeneration of tree species in areas of shifting
cultivation. The extract has been used to stop
bleeding and in wound healing in many tropical
countries. It also contains a master regulator of
genes with defensive anti-inflammatory and
detoxifying functions.(9)

In many communities, individuals squeeze
and paste these leaves regularly on the affected
portion of the injured vessels which stops the
bleeding in a short time. The nutritional and

medicinal benefits of these vegetables assist in
combating malnutrition, prevention of many
diseases as well as contributing to the food
security system in rural areas. (4)

Medicinal plants have formed the basis of
health care throughout the world since the earliest
days of humanity and have remained relevant in
both the developing and developed nations for
various chemotherapeutic purposes.(10) The use
of plant- derived natural compounds as part of
herbal preparations form an alternate source of
medication. The leaf extr act of Vernonia
amygdalina ha s be en found to possess
ethnomedical and pharmacological properties,
such as antidiabeti c, antimalarial and
antihelminthic effects.(11,12)

Previous studies done on this leaf extract
investigated the first-line routine investigation in
bleeding episodes and the healing process.(12) Our
study went further to investigate specific clotting
factors and added that increase in D-dimer levels
was responsible for the reduction in prothrombin
time (PT), stoppage of bleeding which will
invariably enhance wound healing. The
combination of these two extracts in bringing this
about has not been previously investigated.

Against this backdrop, this work was
carried out to evaluate the effect of Vernonia
amygdalina and Chromolaena odorata leave
extracts on some haemostatic parameters using
Wistar rats.

METHODS

Research design
The extracts of both leaves were analyzed

to identify the active ingredients using methods
described by Sofowora.(13) Acute toxicity studies
using LD

50
 was carried out before the leaf

extracts were administered to the rats. This work
was carried out between January and August, 2017
in Benin City, Edo State, Nigeria.

Collection and preparation of plant extract
Fresh specimens of Vernonia amygdalina

and Chromolaena odorata leave s wer e



133

harvested in a farm land in Benin City and
identif ie d by a qua lif ie d Pha rmacist/
Pharmacologist. The extract of the leaves was
prepared at the Pharmacognosy Laboratory,
Faculty of Pharmacy, University of Benin. The
registration numbers of the leaves were UBW/
PCG/1024 and UBW/PCG/1025 for Vernonia
amygdalina and Chrom olae na od orata
respectively.

Acute toxicity testing
The median lethal dose (LD

50
) is a common

test used to evaluate acute toxicity. This was
done on twenty (20) rats, using two (2) rats for
each concentration by the standard method.
Phytochemical screening on both leaves was
d on e  b y me t ho ds  de s c r ib e d  by va r i ou s
researchers.(13,14)

Animal treatment
A total of 35 apparently healthy Wistar rats

of both sexes weighing between 140-180 g,
o bt a i n e d  f r o m t he  a ni ma l  h ou s e  of  t he
Department of Anatomy, University of Benin,
were sorted for the haemostatic evaluation. All
experimental animals were fed with standard
animal feed and water ad libitum.

Sample size determination
This was calculated using the Resource

Equation
E = Total number of animals “ Total number of
groups
Where E is the degree of freedom of analysis of
variance (ANOVA). The value of E should lie
between 10 and 20. If E is less than 10 then adding
more animals will increase the chance of getting
more significant results.(15)

Experimental animals
Group 1 received 150mg/kg body weight

extract of Vernonia amygdalina (VA). Group
2 received 250mg/kg body weight VA. Group 3
r e c e i ve d  15 0mg/ kg b o dy w e i gh t  e xt r a c t
Chromolaena odorata (CO). Group 4 received

250mg/kg body weight extract Chromolaena
odorata (CO). Group 5 received 150mg/kg
body weight extract combined extract VA/CO.
Group 6 received 250mg/kg body weight extract
combined extract VA/CO leaves. Group 7
served as control group and received water. Leaf
extracts were administered once daily via
orogastric intubation for 30 days.

Collection of blood samples
The rats were euthanized under mild

c o nc e nt r ati o n  of  c h l or of or m va p or  a n d
sacrificed. Whole blood was collected via
cardiac puncture using sterile syringes into
EDTA bottles for full blood count and into
trisodium citrate bottles for haemostatic factor
assay.

Determination of haemostatic parameters
Quantitative estimation of protein C

The enzyme linked immunosorbent assay
(ELISA) method was used. The micro ELISA
plate was pre-coated with an antibody specific
to protein C. Standards and samples were added
to the appropriate micro-ELISA plate wells and
combined with the specific antibody. A biotinylated
detection antibody specific for protein C and
Avidin-Horseradish peroxidase (HRP) conjugate
was added to each micro plate successively and
the plate incubated. Free components were
washed away. The substrate solution was added
to each well. The enzyme-substrate reaction was
terminated by the addition of a stop solution
(sulphuric acid solution) to form a yellow colour.(16)

Estimation of factor VII
One hundred microlitres of standard and

sample were added to separate tubes, 100μl of
prepared detection reagent A was added and
incubated for 1 hr at 37o C. They were washed
three times using normal saline, 90μl of substrate
solution was added and incubated for 30 minutes
at 37oC. Finally 50μl stop solution was added
a n d t h e  op t i c a l  d e ns i t y ( O D)  r e a d
spectrophotometrically at 540nm.(16)

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Matthew, Osime                                                                         Vernonia amygdalina and Chromolaena odorata on haemostasis

Estimation of D-dimers
Fifty microlitres of standard and sample

was measured in separate test tubes. Forty
microlitres of biotinylated detection antibody
was added immediately and incubated for 45
minutes at 37o C, then washed three times using
normal saline. Ninety microlitres of substrate
reagent was added and incubated at 370C for
15minutes. Fifty microlitres of stop solution was
added and the optical density read at 450nm
immediately.(16)

Estimation of plasma fibrinogen concentrate
(FC)

This was done using Ingram’s clot weight
methods. When calcium chloride is added to
citrated plasma, the intrinsic pathway is triggered,
resulting in‘ the formation of a fibrin clot, which
can be collected and dried; the weight of
fibrinongen obtained is directly proportional to
the amount of fibrinogen present.(16)

Determination of clotting time (CT)
The principle of clotting time is based on

the time required for a sample of blood to
coagulate in vitro under standard conditions. Blood
samples collected were immediately placed in test
tubes which were already pre-warmed to a
temperature of 37°C in a water bath, and timing
was done immediately with a stop watch. The
tubes were swirled gently at 30 second intervals
to observe for clot formation. As soon as a clot
was observed, the timer was stopped and the time
recorded in minutes.

Determination of prothrombin time (PT)
The Diagen diagnostic reagent was used.

The PT test measures the clotting time of plasma
in the presence of optimal concentrations of
thr omboplastin and indic ate s the overall
efficiency of the extrinsic clotting system.

In the presence of calcium ions, tissue
thromboplastin initiates the extrinsic coagulation
pathway by the direct activation of factor VII
to VIIa. This culminates in the conversion of
soluble fibrinogen to insoluble fibrin by the direct

a c t i o n of  th r o mbi n . A r e du c ti on  i n  t he
concentration of clotting factors of the extrinsic
and common pa thways will result in the
prolongation of the PT, the degree of which is
proportional to the level of concentration
reduction.

Act ivat ed parti al t hrom bopl asti n ti me
(APTT)

This was also done using Diagen diagnostic
reagent. It is a measure of the combined effect
of the clotting factors of the intrinsic and
common coagulation pathways. It represents the
ultimate refinememt in which platelet activity is
standardized by the use of platelet substitutes
and contact activation is standardized by pre-
incubation of the plasma with the kaolin platelet
substitute mixture for a standard time before re-
calcification.(16)

Statistical analysis
Result obtained were expressed as mean

± standard error of mean (SEM). Differences
were  dete rmined by one-way analysis of
variance (ANOVA). Computer software used
was Graph pas instat Version 2.05 software/UK.
Level of significance was at p<0.05.

Ethical clearance
All the experiments were performed in

accordance with the guidelines for care and use
of laboratory animals of the Faculty of Pharamacy,
University of Benin. The registration numbers of
the leaves were UBW/PCG/1024 and UBW/
PCG/1025 for VA and CO respectively.

RESULTS

There was a significant decrease in PT
(p<0.05), CT and FC (p<0.01) in rats treated
with 150mg/kgBW of the combined extracts
when compared to controls (Table 1). D-dimer
levels were observed to increase significantly
(p<0.05) in rats treated with 150mg/kgBW of
VA and VA/CO extracts when compared with
the controls (p<0.05) (Table 2).

h B C



135

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136

Matthew, Osime                                                                         Vernonia amygdalina and Chromolaena odorata on haemostasis

DISCUSSION

In this study, the haemostatic activities of
VA and CO leaf extract was evaluated. There
was a significant reduction in the PT and CT at
1 50 mg/ kgBW  an d  2 40mg/kgBW  of b ot h
extracts. This may be attributed to the high levels
of calcium, vitamin C, proteins and saponins
present in the leaves. Although calcium is the
principal active ingredient present in plasma and
bones, it is the free calcium ions that are
physiologically active in the coagulation
mechanism. This agrees with another research
finding,(9) which demonstrated that the leaves
of VA would stop bleeding if squeezed and
placed on cuts and wounds of injured vessels.
Calcium is essential in the conversion of
prothrombin to thrombin. Vernonia amygdalina
and CO leave extracts have been reported to
be rich in antioxidant and flavonoids.(17,18) The
high antioxidant levels present in the extracts
may act in synergy with other phytochemicals
which activate endothelial cells to synthesize
tissue factors thus promoting haemostasis. Plant
e x t r a c t s  ar e  a dmi ni s t e r e d t o hu ma ns  i n
u nco n tr ol l ed  d os e s  by th e  e th n ome d ic a l
practitioners. These activities of leaf extracts
on blood parameters provides some physiological
information on the blood assessment in the
body.(18)

There was significant reduction in fibrinogen
levels with the extract concentrations at 150mg/
kgBW of VA and CO and at 250mg/kgBW of
combined extracts when compared with the
controls. Fibrinogen is an acute phase protein and
its concentration rises in a variety of non-specific
conditions such as inflammation, trauma and
myocardial infarction. The reduction of fibrinogen
in this study indic ates that VA and CO
administration reduces and prevents inflammation
which may be largely attributed to the presence
of flavonoids as contained in the phytochemical
constituents of the leaf extracts. High levels of
fibrinogen are associated with thrombotic
complications. It has been observed that
individuals with a fibrinogen level greater than

4g/L have a two-fold increased risk of venous
thrombosis.(24) Methanolic extracts of VA of
100mg/kgBW and 200mg/kgBW could reduce
40% and 50% inhibition against thrombosis in
mice.(20,21)

Administration of the extracts did not
significantly alter the concentrations of factor VII
and protein C when compared with the controls.
This may indicate that the leaf extract in
enhancing blood clotting does not directly lead to
increased production of these clotting factors. D-
Dimers are present in the blood of most healthy
individuals in only negligible amounts. Elevated
blood levels of D-dimers is evidenced by increase
fibrinolysis and thrombotic episodes.(22)

In this study, administration of 250mg/kg
BW of VA and 150mg/kgBW of combined VA/
CO showed a significant increase in D-dimer
levels when compared with the controls. This
suggests that the extract enhances fibrinolysis
thereby facilitating the healing of an injured
vessel. Extracts of VA have been shown to have
antimicrobial and antiseptic properties.(23) This
may also act as a protective mechanism enhancing
the complete healing of injured vessels with the
administration of these extracts.

The combined effect of VA and CO to
injuries especially superficial wounds would
reduce hemorrhage. This also has revealed a
channel to phar mace utical companies to
incorporate these extracts in drugs used in
preventing haemorrhage. Although the present
findings suggest the presence of hemostatic
compounds in leaf extract of VA and CO, the
precise mechanism of its hemostatic action is still
speculative and requires further studies for
appropriation elucidation.

CONCLUSION

The leave extracts of VA and CO shorten
the protrombin time, clotting time and decrease
fibrinogen levels while D-dimer levels are
increased. This implies that the administration of
these leave extracts goes a long way in the
stoppage of bleeding and aids fibrinolysis.



137

CONFLICT OF INTERESTS

We declare that there is no conflict of
interest

ACKNOWLEDGEMENT

We acknowledge the non-accademic staff
of the Department of Anatomy for helping to take
care of the animals during the research duration.

AUTHORS CONTRIBUTION

MOL conceived th e study and was
responsible for the experimental design and
practical implementation. OEO contributed to the
experimental design and did the manuscript write-
up. All authors have read and approved the final
manuscript.

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