ABSTRACT
The potential effect of methanolic extract of the leaves of Acalypha
wilkesiana on the weight of wistar rats was investigated. Calculated
amount of methanolic leaf extract of Acalypha Wilkesiana were
constituted in distilled water from the stock solution to give doses of
500,500 and 1000 mg/kg body weight of paracetamol, vitamin C and leaf
extract respectively and administered to the various groups (A, B, C and
D). Prior to the administration of methanolic leaf extract of Acalypha
Wilkesiana at every interval of seven days, the body weights of the
animals were recorded. The acute administration of the aqueous leaf
extract of Acalypha wilkesiana did not result in obvious signs of
morphological changes or death of male rats throughout the experimental
period. A significant difference (P>0.05) was obtained in the average
body weight of animals administered with the extract as compared with
the paracetamol treated group. The organ weight also elucidated no
significant differences (P<0.05) in the kidney, brain, heart, lung
and pancreas except for the liver where there was an increase in the
weight of the liver treated with extract as compared to that of the rats
treated with paracetamol. From the results obtained it is shown that
the extract altered the weight of the liver and is therefore not
hepatoprotective, this extract should undergo further investigation
before oral administration is recommended.
CHAPTER ONE
INTRODUCTION AND LITERATURE REVIEW
1.1 MEDICINAL PLANTS
The use of plants for healing purposes has always been part of human
culture and it is getting increasingly popular in Nigeria. Acalypha
wilkesiana is one of several medicinal plants used in Nigeria and it has
various ethno botanical uses. Acalypha wilkesiana belongs to the family
Euphorbiaceae. It is propagated by stem cuttings at any time of the
year. Under ideal conditions, it grows as a spreading evergreen shrub
with upright branches that tend to originate near the base and can get
up to 3.1 m tall with a similar spread. It has leafs (12.7- 20.3 cm
long) that are alternate, elliptic to oval, serrate and multi-coloredans
small inconspicuous flowers (10.2-20.3 cm) that hangs in catkin-like
racemes beneath the foliage
(Al-attar, 2010).
In some parts of southern Nigeria, the use of diuretics in the
treatment of hypertension has been traditionally substituted for aqueous
leaf extract of Acalypha wilkesiana. Acute changes in body mass over a
short time period can frequently be assumed to be due to body water loss
or gain; 1 ml of water has a mass of 1 g and therefore changes in body
mass can be used to quantify water gain or loss. Over a short time
period, no other body component will be lost at such a rate, making this
assumption possible (Shirreffs, 2003), thus weight parameters were
evaluated and used as makers of hydration status of the male Wistar
rats.
ACALYPHA SPECIE
Kingdom: Plantae
Order: Malpighiales
Family: Euphorbiaceae
Subfamily: Acalyphoideae
Tribe: Acalypheae
Subtribe: Acalyphinae Genus Acalypha
Acalypha is a plant genus of the family Euphorbiaceae. It is the sole
genus of the subtribe Acalyphinae. With 450 to 500 species of shrubs,
trees and annuals, the genus is only behind Euphorbia, Croton and
Phyllanthus in terms of Malpighiales diversity. The common name is
copperleaf, three-seeded mercury or cat’s tail (Pax et al, 1924). These
plants are mostly tropical or subtropical, with a few representatives in
temperate zones. The Americas contain two thirds of the known species,
distributed from southern United States to Uruguay and northern
Argentina. Several species, such as Acalypha ecuadorica, Acalypha
eggersii and Acalypha raivavensis are nearly extinct, and the St. Helena
Mountain Bush or “stringwood” Acalypha rubrinervis already is hispida
(chenille plant, red-hot cat’s tail), cultivated as a houseplant because
of its colourful and texturally exciting flowers, has gained the Royal
Horticultural Society’s Award of Garden Merit. (Grubben et al, 2004), as
has Acalypha hispaniolae (Hispaniola cat’s tail). Others are grown for
their foliage and a number of cultivars have been developed, such as
Acalypha wilkesiana ‘Obovata Cristata’ and Acalypha wilkesiana Acalypha
wilkesiana “Hoffmannii’. Acalypha bipartita is eaten as a vegetable in
some parts of Africa.
1.1.2 ACALYPHA WILKESIANA
Kingdom: Plantae
Order: Malpighiales
Family: Euphorbiaceae
Genus: Acalypha
Species: Acalypha wilkesiana
Binomial name: Acalypha wilkesiana
Acalypha wilkesiana is an evergreen shrub. It grows 3 m high and
spreads 2 m across. The stem is erect with many branches. The branches
have fine hairs. It has a closely arranged crown. The leaves are coppery
green with red splashes of colour. This gives them a mottled
appearance. The leaves are large and broad with teeth around the edge.
They can be 10–20 cm long and 15 cm wide. The leaves are finely hairy.
They can be flat or crinkled. The flowers are reddish in spikes at the
end of branches. They have separate male and female flowers on the same
plant. The male flowers are in long spikes which hang downwards while
the female flowers are in short spikes. They do not show up easily as
they are often hidden among the leaves. The flower stalks are 10–20 cm
long. A tropical and subtropical plant which grows naturally in Vanuatu.
It occurs in the Pacific Islands. It prefers light well drained soil.
It suits a protected shady position. It is damaged by both drought and
frost. It needs a minimum temperature above 10°C. It suits hardiness
zones 9-12. Acalypha wilkesiana ointment is used to treat fungal skin
diseases (Oyelami et al, 2003) carried out a non-comparative study to
evaluate the safety and efficiency of Acalypha wilkesiana ointment using
32 Nigerians with mycological as well as clinical evidence of
mycoses. The ointment successfully controlled the mycoses in 73.3% of
the affected patients. It was very effective in treating Pityriasis
versicolor, Tinea pedia and Candida intetrigo, with 100% cure (Oyelami
et al, 2003) concluded that Acalypha wilkesiana ointment can be used to
treat superficial mycoses (Akinyemi et al, 2005) evaluated crude
extracts from six important medicinal plants, namely: Phylantus
discoideus, Ageratum conyzoides, Terminalia avicennioides, Bridella
ferruginea, Acalypha wilkesiana and Ocimum gratissimum, to find activity
against methicillin resistant Staphylococcus aureus
(MRSA. Water and ethanolic extracts of these plants were obtained
locally. MRSA strains isolated from patients were used. Both ethanolic
and water extracts showed effects on MRSA. Minimum bactericidal
concentration (MBC) and minimum inhibition concentration (MIC) of these
plants ranged from 30.4-37.0 mcg/ml and 18.2-24.0 mcg/ml respectively. A
high MBS value was found in two plants and the other four contained
traceable amounts of anthraquinones. This study provided scientific
support for the use of Acalypha wilkesiana, T. avicennioides, O.
gratissimum and P. discoidens against MRSA based diseases. A. conyzoides
and B. ferruginea were unresponsive against the MRSA strains (Oyelami
et al, 2003).
PARACETAMOL
Fig 1: structure of paracetamol
Paracetamol (called acetaminophen in the USA) is one of the most
commonly used non-narcotic analgesic and antipyretic agents. It has
relatively weak anti-inflammatory activity. Paracetamol is reported to
be selective inhibitor of Cox 3 (cyclooxygenase). Although some reported
evidence show that paracetamol has significant anti- inflammatory
action (Granberg et al, 1999). Paracetamol toxicity is one of the most
common causes of poisoning worldwide. In the United States and United
Kingdom it is the most common cause of acute liver failure. Paracetamol
was the fourth most common cause of death following self-poisoning in
the United Kingdom in 1989; (karthikeyan et al., 2005), yet it is still
one of the most common analgesic and antipyretic drugs often used around
the world to treat pains and mild feverish conditions. As far as this
is true, it is also one of the major causes of liver damage such as
liver necrosis. Traditionally, a number of herbal medicines have been
used in ameliorating this problem of hepatotoxicity such as fresh
garlic; (moller et al, 2009), methanolic extract of Acalypha wilkesiana;
(khashab et al, 2007).Toxic doses of paracetamol cause a serious
potentially fatal hepatotoxicity.
MEDICAL USES OF PARACETAMOL
In medicine paracetamol is used to;
Reduce Fever:
Paracetamol is approved for reducing fever in people
of all ages. The World Health Organization (WHO) recommends that
paracetamol only be used to treat fever in children if their temperature
is greater than 38.5 °C (101.3 °F). The efficacy of paracetamol by
itself in children with fevers has been questioned and a meta-analysis
showed that it is less effective than ibuprofen. Paracetamol has a
well-established role in pediatric medicine as an effective analgesic
and antipyretic.
Reduce Pain:
Paracetamol is used for the relief of pains
associated with many parts of the body. It has analgesic properties
comparable to those of aspirin, while its anti-inflammatory effects are
weaker. It is better tolerated than aspirin in patients in whom
excessive gastric acid secretion or prolongation of bleeding time may be
a concern. Available without a prescription, it has in recent years
increasingly become a common household drug.
1.2.2 PARACETAMOL INDUCED HEPATOXICITY
The toxic effect of paracetamol on the liver occur when the liver
enzymes catalyzing the normal conjugation reactions are saturated,
causing the drug to be metabolized by the mixed function oxidases. The
resulting toxic metabolized, N-acetyl-p- benzoquinoneimine (NAPQI), is
inactivated by conjugation with glutathione, but when glutathione is
depleted the toxic intermediate accumulates and reacts with nucleophilic
constituents in the cell. This causes necrosis in the liver and also in
the kidney tubules.
MECHANISM OF ACTION OF PARACETAMOL ON HEPATOXICITY
Metabolic
activation of acetaminophen toxicity is metabolically activated by
cytochrome P450 to form a reactive metabolite that covalently binds to
protein (Mitchell et al,). The reactive metabolite was found to be
N-acetyl-p-benzoquinone imine (NAPQI), which is formed by a diret
to-electron oxidation (Dahlin et al, 1984). More recently, the
cytochromes 2E1, 1A2, 3A4, and 2A6 have been reported to oxidize
acetaminophen to the reactive metabolite. Also, Dr. Gillette’s
laboratory showed that NAPQI is detoxified by glutathione (GSH) to form
an acetaminophen-GSH conjugate. After a toxic dose of acetaminophen,
total hepatic GSH is depleted by as much as 90%, and as a result, the
metabolite covalently binds to cytokine groups on protein, forming
acetaminophen-protein adducts (Mitchell et al, 1973). This mechanism is
shown in Fig. 2.
Fig 2: showing the schematic representation depicting the role of
Metabolism in acetaminophen toxicity (Mitchell et al, 1973)
Events that produce hepatocellular death following the formation of
acetaminophen protein adducts are poorly understood. One possible
mechanism of cell death is that covalent binding to critical cellular
proteins results in subsequent loss of activity or function and eventual
cell death and lysis. Primary cellular targets have been postulated to
be mitochondrial proteins, with resulting loss of energy production, as
well as proteins involved in cellular ion control (Nelson, 1990).
1.3 WEIGHT
1.3.1 WEIGHT DETERMINATION
Prior to this research the weight of these wistar rats were determined using
A beam balance: this instrument was used to measure the body weight of the rats
An electronic weigh balance: this instrument was used to measure the organ weight of the rats
1.3.2 WEIGHT ASSOCIATED DISEASES
Excess body weight is a very serious problem, especially in North
America and Europe. It has been referred to as a “pandemic” since it has
progressively increased over the past several decades. Moreover, excess
body weight significantly increases the risk of numerous diseases and
clinical disorders, including all-cause mortality, coronary and
cerebrovascular diseases, various cancers, type 2 diabetes mellitus,
hypertension, liver disease and asthma, as well as psychopathology,
among others. Unfortunately, overweight and obesity are now common in
both young children and adolescents. Although the causes of excess body
weight are multi-factorial, the most important factors are excess
caloric intake coupled with limited energy expenditure. Therefore,
lifestyle modification can significantly reduce the risk of morbidity
and mortality and thereby increase longevity and improve the quality of
life.
1.4 ORGAN WEIGHT OF RATS
1.4.1 THE LIVER
The liver is a vital organ present in vertebrates and some other
animals. It has a wide range of functions, including detoxification,
protein synthesis, and production of biochemicals necessary for
digestion. The liver is necessary for survival; there is currently no
way to compensate for the absence of liver function in the long term,
although new liver dialysis techniques can be used in the short term.
This organ plays a major role in metabolism and has a number of
functions in the body, including glycogen storage, decomposition of red
blood cells, plasma protein synthesis, hormone production, and
detoxification. It lies below the diaphragm in the abdominal-pelvic
region of the abdomen. It produces bile, an alkaline compound which aids
in digestion via the emulsification of lipids. The liver’s highly
specialized tissues regulate a wide variety of high-volume biochemical
reactions, including the synthesis and breakdown of small and complex
molecules, many of which are necessary for normal vital functions.
The liver is a reddish brown organ with four lobes of unequal size
and shape. A human liver normally weighs 1.44–1.66 kg (3.2–3.7 lb), and
is a soft, pinkish-brown, triangular organ. It is both the largest
internal organ (the skin being the largest organ overall) and the
largest gland in the human body. It is located in the right upper
quadrant of the abdominal cavity, resting just below the diaphragm. The
liver lies to the right of the stomach and overlies the gallbladder. It
is connected to two large blood vessels, one called the hepatic artery
and one called the portal vein. The hepatic artery carries blood from
the aorta, whereas the portal vein carries blood containing digested
nutrients from the entire gastrointestinal tract and also from the
spleen and pancreas. These blood vessels subdivide into capillaries,
which then lead to a lobule. Each lobule is made up of millions of
hepatic cells which are the basic metabolic cells. Lobules are the
functional units of the liver.
Two major types of cells populate the liver lobes: karat parenchymal
and non-parenchymal cells. 80% of the liver volume is occupied by
parenchymal cells commonly referred to as hepatocytes. Non-parenchymal
cells constitute 40% of the total number of liver cells but only 6.5% of
its volume. Sinusoidal endothelial cells, Kupffer cells and hepatic
stellate cells are some of the non-parenchymal cells that line the
hepatic sinusoid. The liver is also prone to many diseases. The most
common include infections such as hepatitis A, B, C, D, E, alcohol
damage, fatty liver, cirrhosis, cancer, drug damage (particularly by
acetaminophen (paracetamol) and cancer drugs). Many diseases of the
liver are accompanied by jaundice caused by increased levels of
bilirubin in the system. The bilirubin results from the breakup of the
hemoglobin of dead red blood cells; normally, the liver removes
bilirubin from the blood and excretes it through bile. There are also
many pediatric liver diseases including biliary atresia, alpha-1
antitrypsin deficiency, alagille syndrome, progressive familial
intrahepatic cholestasis, and Langerhans cell histiocytosis, to name but
a few. Diseases that interfere with liver function will lead to
derangement of these processes. However, the liver has a great capacity
to regenerate and has a large reserve capacity. In most cases, the liver
only produces symptoms after extensive damage.
Liver diseases may be diagnosed by liver function tests, for example, by production of acute phase proteins.
1.4.2 THE KIDNEY
The kidneys are organs that serve several essential regulatory roles
in most animals, including vertebrates and some invertebrates. They are
essential in the urinary system and also serve homeostatic functions
such as the regulation of electrolytes, maintenance of acid–base
balance, and regulation of blood pressure (via maintaining salt and
water balance). They serve the body as a natural filter of the blood,
and remove wastes which are diverted to the urinary bladder. In
producing urine, the kidneys excrete wastes such as urea and ammonium,
and they are also responsible for
the reabsorption of water, glucose, and amino acids. The kidneys also
produce hormones including calcitriol, erythropoietin, and the enzyme
renin.
1.4.3 THE HEART
The heart is a hollow muscle that pumps blood throughout the blood
vessels by repeated, rhythmic contractions. It is found in all animals
with a circulatory system (including all vertebrates). The vertebrate
heart is principally composed of cardiac muscle and connective tissue.
Cardiac muscle is an involuntary striated muscle tissue found only in
this organ and responsible for the ability of the heart to pump blood.
The average human heart, beating at 72 beats per minute, will beat
approximately 2.5 billion times during an average 66 year lifespan. It
weighs approximately 250 to 300 grams (9 to 11 oz) in females and 300 to
350 grams (11 to 12 oz) in males.
1.4.4 THE BRAIN
The brain is the centre of the nervous system in all vertebrate and
most invertebrate animals—only a few invertebrates such as sponges,
jellyfish, adult sea squirts and starfish do not have one, even if
diffuse neural tissue is present. It is located in the head, usually
close to the primary sensory organs for such senses as vision, hearing,
balance, taste, and smell. The brain of a vertebrate is the most complex
organ of its body. In a typical human the cerebral cortex (the largest
part) is estimated to contain 15–33 billion neurons, each connected by
synapses to several thousand other neurons. These neurons communicate
with one another by means of long protoplasmic fibres called axons,
which carry trains of signal pulses called action potentials to distant
parts of the brain or body targeting specific recipient cells.
1.4.5 THE TESTES
The testicle (from Latin testiculus, diminutive of testis, meaning
“witness” of virility,plural testes) is the male gonad in animals. Like
the ovaries to which they are homologous, testes are components of
both the reproductive system and the endocrine system. The primary
functions of the testes are to produce sperm (spermatogenesis) and to
produce androgens, primarily testosterone. Both functions of the
testicle are influenced by gonadotropic hormones produced by the
anterior pituitary.
1.4.6 THE LUNGS
The lung is the essential respiration organ in many air-breathing
animals, including most tetrapods, a few fish and a few snails. In
mammals and the more complex life forms, the two lungs are located near
the backbone on either side of the heart. Their principal function is to
transport oxygen from the atmosphere into the bloodstream, and to
release carbon dioxide from the bloodstream into the atmosphere. This
exchange of gases is accomplished in the mosaic of specialized cells
that form millions of tiny, exceptionally thin-walled air sacs called
alveoli.
1.5 OBJECTIVE OF STUDY
The objective of this study is to determine the effect of methanolic
leaf extract of Acalypha wilkesiana in paracetamol induced hepatoxicity
on the weight parameters of Wistar rats.