ABSTRACT
Medicinal plants are traditional plants/herbs that have been used in healthcare centers to treat various types of illness. Examples of medicinal plants are Dogoyaro leaf, paw-paw leaf, e.t.c. Medicinal plants have a long history of use and their use is widespread in both developing and developed countries. The study evaluated the antibacterial effect of Dogoyaro (Azadirachta indica) leaf on pathogenic organisms. The fresh leaves of Dogoyaro (Azadirachta indica) leaves were collected at National Root Crop Research Institute Umudike in Ikwuano, Abia State, Nigeria. The plant was identified and authenticated at the Herbarium of the Department of Plant sciences and Biotechnology, Michael Okpara university of Agriculture, Umudike, Abia State. The antibacterial activity of Dogoyaro (Azadirachta indica) leaf extracts on some pathogens was investigated with different solvents (Ethanol and aqueous) against test organisms (Staphylococcus aureuas, Esherichia coli and Pseudomonas aeruginosa) using agar well diffusion method. The different extracts were prepared at different concentration (200mg/ml, 100 mg/ml, 50mg/ml, 25 mg/ml, 12.5 mg/ml and 6.25mg/ml). Amongst the different Dogoyaro (Azadirachta indica) leaf extracts studied, the ethanolic extracts have more significant inhibitory effect than the aqueous extracts. The diameter zone of inhibition (mm) produced by ethanolic and aqueous leaf extract of the Dogoyaro (Azadirachta indica) indicated that the aqueous extracts of Dogoyaro (Azadirachta indica) showed minimal antibacterial activity against the isolates at 200 mg/ml, 100 mg/ml, 50 mg/ml and 25 mg/ml concentrations as against the ethanolic extracts. The results also show that as the concentrations of the extract increases there is a corresponding increase in the zones of inhibition and comparing the activity, ethanolic extract of neem leaf exhibited higher antimicrobial activity against the test bacteria than aqueous extract. This difference may be due to the inhibitory ability of the ethanol even without extract, whereas the ability of the aqueous extract to exhibit this inhibition may be primarily due to its penetrative ability. From this study, it was observed that ethanol extracts exhibited better MIC and MBC on the test organisms. The present work has shown that Staphylococcus aureus, Escherichia coli and Pseudomonas aeruginosa were susceptible to extracts of Dogoyaro (Azadirachta indica) which means the plant has antibacterial property. The results of this study suggest that the leaf of Dogoyaro (Azadirachta indica) can be used as an antibacterial agent against infections caused by Staphylococcus aureus, Escherichia coli and Pseudomonas aeruginosa.
TABLE OF
CONTENTS
Title
Page i
Certification iii
Dedication iv
Acknowledgements v
Table
of Contents vi
List
of Tables ix
Abstract x
CHAPTER ONE
1.0 Introduction 1
1.1 Aims and Objectives 5
CHAPTER TWO
2.0 Literature
Review 6
1.1 Azadirachta Indica 6
2.2 Medicinal
Uses 7
2.3 Phytochemicals 8
2.4 Antimicrobial
Activity 9
2.4.1 Antibacterial and Anti-Fungal Activities 10
2.5 Antibacterial
Effects of Crude Extract of Azadirachta
Indica against
Escherichia coli, Salmonella sp and Staphylococcus aureus 10
2.6 Test Organisms 12
2.6.1 Escherichia
coli 12
2.6.2 Staphylococcus aureus 14
2.6.3 Pseudomonas aeruginosa 14
CHAPTER THREE
3.0
Materials and Methods 16
3.1 Study
Area 16
3.2 Materials 16
3.3 Sample
Collection 16
3.4 Test
Organisms 17
3.5 Confirmation
of Test Isolate 17
3.5.1 Morphological appearance 17
3.5.2 Gram Staining 17
3.5.3 Motility test 18
3.5.4 Biochemical tests 18
3.6 Preparation
of Crude Extracts 20
3.7 Preparation
of Concentration of Plant Extract 21
3.8 Antimicrobial
Susceptibility Testing 21
3.9 Determination
of Minimum Inhibitory Concentration (MIC) 22
3.10 Minimum
Bactericidal Concentration (MBC) 22
CHAPTER FOUR
4.0 Result 23
CHAPTER FIVE
5.0 Discussion, Conclusion and Recommendation 31
5.1 Discussion 31
5.2 Conclusion
33
5.3 Recommendation
33
References 34
LIST OF
TABLES
|
TABLE
|
TITLE
|
PAGE
|
|
4.1
|
Morphological characteristics of the Isolates
|
25
|
|
4.2
|
Biochemical Identification of Isolates
|
26
|
|
4.3
|
Diameter zone of inhibition (mm) produced by ethanol leaf
extract of the Dogoyaro (Azadirachta
indica)
|
27
|
|
4.4
|
Diameter zone of inhibition (mm) produced by aqueous leaf
extract of the Dogoyaro (Azadirachta
indica)
|
28
|
|
4.5
4.6
|
MIC and MBC values (mg/ml) of the ethanol extracts against
susceptible organisms
|
29
|
|
MIC and MBC values (mg/ml) of the aqueous extracts against
susceptible organisms
|
30
|
CHAPTER ONE
1.0 INTRODUCTION
Plants have formed the basis of traditional systems of
medicine that have been in existence since time immemorial and continued to
provide mankind with new remedies (Jonathan et
al., 2007). A medicinal plant is one which contains substances that can be
used for therapeutic purposes. For a long time, plants have been valuable and
indispensible sources of natural products for the health of human beings and
they have a great potential for producing new drugs (Nascimento et al., 2000). Plants act generally to
stimulate and supplement the body’s forces; they are the natural food for human
beings (Akinnibosun and Itedjer 2012). For thousands of years before the advent
of modern medicine, herbs and substances derived from plants have been the
mainstay of traditional medicine around the world (Ortuno et al., 2006). According to World Health Organization, medicinal
plants would be the best source to obtain varieties of drugs. About 80% of
individuals from developed countries have used traditional medicine, which has
compounds derived from plants. Therefore, such plants should be investigated
for better understanding of their properties, safety and efficiency
(Chintamunnee and Mohomoodally 2012).
Mouhssen (2013), because of an increasing interest in plants as source
of agents to fight microbial diseases and the alarming incidence of antibiotic
resistance of pathogenic microbes in particular, there is still constant need
for discovering new and effective therapeutic agents. The control of infectious
diseases is badly endangered by the rise in the number of Microorganism that
are resistant to antimicrobial agents. This is because infectious caused by
resistant Microorganisms often fail to respond to conventional treatment,
resulting in prolonged illness and greater risk of death. Antibiotics
resistance is a type of drug resistance where Microorganisms are able to
survive exposure to an antibiotic. The primary causes of antibiotic resistance
are genetic mutation in bacteria (Fernando and Jose 2013). Inappropriate and irrational use of
antimicrobial medicines provides favourable conditions for resistant
Microorganisms to emerge, spread and persist. The greater the duration of
exposure to the antibiotic, the greater the risk of the development of
resistance, irrespective of the need for the antibiotic as resistance toward
antibiotics becomes more common, a greater need for alternative treatment
arises. However despite a push for new antibiotic therapies there has been a
continued decline in the number of newly approved drugs (Mankkam et al., 2015). Antibiotics resistance
therefore posses a significant problem. Nevertheless efforts are in place to
solve the problem. Nowadays, bacteria are considered
as the main cause of morbidity and mortality in many developing countries,
especially amongst children. Among the bacterial pathogens, Escherichia coli, Salmonella specie, and Staphylococcus
aureus are most prevalent. In the recent decades despite developments of
different types of antibiotics by pharmacological industries, resistance to
antibiotics has been increased significantly in many bacterial pathogens. In
general, bacteria have several genetic mechanisms to transmit and acquire
resistance to antibiotics. The antibacterial resistance in the bacterial
populations is rapidly spreading; this is a serious threat to successful
treatment of infectious diseases. On the other hand, the side effects associated
with the commercial antibiotics are frequently reported. In this regard, there
is an urgent and continuous need for finding and investigating novel
antimicrobial compounds. Most of the antibiotics have been developed from
microorganisms. Moreover, the plant materials remain an important resource for
finding the novel antimicrobial compounds. There are many published reports on
the antibacterial effectiveness of the traditional herbs against the
gram-positive and gram-negative bacteria. Microbial cells are negatively
affected by plant-derived substances via various mechanisms of actions as these
substances attack the phospholipid bilayer of the cell membrane and disrupt
enzymatic systems (Ahmad et al.,
2006). The medicinal herbs have the bacteriostatic
effects on the enzymatic activity associated with energy production, or they
can cause denaturation of proteins, modifying cell wall permeability, or
causing the loss of macromolecules. Therefore, it is difficult for the
microorganisms to develop resistance against these medicinal herbs.
Medicinal plants have a long history of use and their use is
widespread in both developing and developed countries. According to reports of
the World Health Organization, 80% of the world’s population relies mainly on
traditional therapies which involve the use of plant extracts or their active
substances. Microorganisms have developed resistance against many antibiotics
due to the indiscriminate use of antimicrobial drugs. Furthermore, antibiotics
are sometimes associated with side effects (Cunha, 2001), whereas there are
some advantages of using antimicrobial compounds of medicinal plants, such as
fewer side effects, better patient tolerance, relatively less expensive,
acceptance due to long history of use and being renewable in nature (Vermani
and Garg, 2002). It is known that more than 400, 000 spp. of tropical flowering
plants have medicinal properties and this has made traditional medicine cheaper
than modern medicine. Some plant decoctions are of great value in the treatment
of diarrhoea or gastrointestinal disorder, urinary tract infections, skin
infections, infertility, wound and cutaneous abscesses (Ergene et al., 2006). The tree, Azadirachta indica of the family
Maliaceae; popularly known as neem
tree or dogon yaro (Hausa) is an evergreen tree, native to the Southeast Asia
and found in most tropical countries. It has been in use since ancient times,
to treat a number of human ailments and also as household pesticide
(Chattopadhyay and Bandyopadhyay, 2005). Extracts from the bark, leaves, fruits
and roots have been used to control leprosy, intestinal helminthosis and
respiratory disorders. Every part of the neem tree has been used as traditional
medicine for house-hold remedy against various human ailments from antiquity.
The tree is still regarded as ‘Village dispensary’. It is a plant known over
2000 years as one of the most versatile medicinal plants having a wide spectrum
of activity. Enterobacteriaceae, the
enteric bacteria are facultative anaerobic Gram-negative rods that live in the
intestinal tract of animals in health and diseases. The Enterobacteriaceae are among the most important bacteria medically.
A number of genera within the family are human and animal intestinal pathogens
(for example, Salmonella, Shigella and
Yersinia). Several others are normal
colonist of the human gastrointestinal tract (for example, Escherichia coli, Enterobacter,
Klebsiella), but these bacteria, as
well, may occasionally be associated with diseases in humans and animals.
Azadirachta
indica also known as neem, is called dogoyaro, atuyabasi ogwuakom
or maina in Yoruba, Igbo and Hausa dialects of Nigeria respectively and is
widely distributed across Nigeria. It is famed to be the most extensively
researched plant so far and its products as popular. (Pritima and Selvaraj,
2008). A. indica belongs to the
family Meliaceae. “Azad dhirakat” is a Persian word meaning an “Excellent or
Noble Tree”. It is native to East India and Myanmar (Burma), Southeast Asia,
West Africa and abundant in all regions of Nigeria irrespective of the local
geography of the region (Pritima and Selvaraj, 2008).
Every part of the tree, including leaf, twig, bark, flower,
fruit, root and seed, is used in one form or another and reputed to have
hypoglycemic activity (Biswas et al.,
2002; Ebong et al., 2008),
antidiabetic activities and other pharmacological and biological properties.
It's a fast growing evergreen tree measuring up to 1.5 meters in diameter with
hard fissured or scaly bark. The leaves are alternate, pinnate with dentate
margins; young leaves are reddish-purple in color. Tiny cream colored flowers,
give raise to green oblong fruits with seeds. Fruits, when ripe turn yellow in
color. The leaves and fruits (raw) are bitter but edible and widely eaten in
Nigeria as “agbo”, an herbal cocktail preparation for malaria and in India as
part of food or for medicinal reasons. It has been reported that Mahatma Gandhi
encouraged scientific investigations of neem tree as part of his revitalization
program of the Indian tradition because he loved the plant so much, and also to
increase commercial interest in the plant.
The Chemical constituents in contain
many bioactive compounds including alkaloids, flavonoids, tri-terpenoids,
phenolic compounds, carotenoids, steroids and ketones. The main active
principle present in neem is azadirachtin, a natural insecticide. Azadirachtin
is a mixture of seven isomeric compounds labeled as azadirachtin A to G and
azadirachtin E is more effective. Other compounds found in the plant include
salannin, volatile oils, meliantriol and nimbin. Neem leaf is effective in
treating various diseases as eczema, ringworm, acne, anti-inflammatory
activities, antihyperglycemic and also used to treat chronic wounds, diabetic
foot and gangrene. It is also believed to remove toxins from the body,
neutralize free radicals and acts as a blood purifier. Recently it has been
used as an anticancer preparation and it has hepato-renal protective activity
and hypolipidemic effects. Boiled neem leaf water makes an excellent antiseptic
to clean wounds, soothes swellings and eases skin problems.
•
AIMS AND
OBJECTIVES
The aim of this study is to evaluate
the antibacterial effect of Dogoyaro (Azadirachta
indica) leaf on pathogenic organisms
The objectives are;
•
To determine the antibacterial effects of Dogoyaro (Azadirachta indica) leaf extract against
some selected pathogens
•
To determine the MIC and MBC of Dogoyaro (Azadirachta indica) leaf extracts.
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