ABSTRACT
This study was to determine the antibiotics resistance profile of E. coli isolated from farm animal in Umuahia metropolis. A total of Forty (40) samples were analyzed in the study of which ten (10) swab samples each were collected from Goats, Sheep, Pigs and Rabbits. These samples were cultured on Blood and MacConkey agar plates using streak plate technique and incubated at 37oC for 24hrs. Escherichia coli strains were identified by standard techniques on the basis of their colonial morphology, Gram staining reaction, motility and biochemical characteristics. Among the forty (40) samples analysed, pig had the highest number positive for E. coli with high percentage occurrence 8(42.1%). The antibiotic susceptibility testing, using disc diffusion techniques reveals patterns with high resistant rates of the isolates to Nalidixic acid, Amoxicillin, Septrin and Ampicilin. The highest sensitivity rates on E. coli were recorded with Ciprofloxacin (94.7%), Streptomycin (78.9%), Oflaxacin (89.5%), and gentamicin (84.2%). The results from this study demonstrated the high antimicrobial resistance amongst E. coli to the commonly prescribed antimicrobial drugs which substantiates the alarming occurrence and ongoing spread of various multi resistant Enterobacteriaceae strains in the human and animal population. There is need for continuous surveillance of antimicrobial resistance trends particularly among organisms resident in the gastrointestinal tract of farm-animals which are implicated in infectious diseases in human.
TABLE OF CONTENTS
Title Page i
Certification iii
Dedication iv
Acknowledgement v
Table of Contents vi
List of Tables vii
Abstract ix
CHAPTER ONE
1.0 Introduction 1
1.1 Aim and Objectives 3
CHAPTER TWO
2.0 Literature Review 4
2.1 Modes of Action of Antibacterial Agents 4
2.1.1 Inhibition of Cell-Wall Synthesis 5
2.1.2 Inhibition of Protein Synthesis 6
2.1.3 Injury to the Plasma Membrane 7
2.1.4 Inhibition of Nucleic Acid Synthesis 7
2.1.5 Inhibition of Essential Metabolites 8
2.2 Antibiotics Resistance Mechanisms 8
2.2.1 Resistance Based on Altered Receptors for a
Drug 9
2.2.2 Decreased Entry of Antibiotics 10
2.2.3 Synthesis of Resistance or Alternative
Pathway 10
2.3 Resistance to B-Lactam Antibiotics 11
2.3.1 Tetracycline Resistance 11
2.3.2 Chloramphenicol Resistance 13
2.4 Factors Contributing to the Emergence of
Resistance 13
2.5 Containment
of Antimicrobial Resistance 14
2.5.1 Infection
Control 14
2.5.2 Rational Use of Antibiotics 15
2.6 Biology and Pathogenecity of E. coli 16
2.6.1 Escherichia
coli 16
2.6.1.1 Diseases
Caused by Escherichia coli O157: H7 17
CHAPTER THREE
3.0 Materials and Methods 18
3.1 Study Location 18
3.2 Sample Collection 18
3.3 Sample Processing 18
3.4 Isolation and Identification of E. coli Isolates 18
3.4.1 Colonial Morphology 18
3.4.2 Gram Staining 19
3.4.3 Motility
Test 19
3.5 Biochemical Tests 19
3.5.1 Catalase Test 19
3.5.2 Methyl Red Test 20
3.5.3 Voges-Proskauer Test 20
3.5.4 Indole Test 20
3.5.5 Citrate Utilization Test 20
3.5.6 Urease
Test 21
3.5.7 Triple
Sugar Iron Agar Test 21
3.6 Antibiotic Sensitivity Testing 21
3.7 Data
Analysis
22
CHAPTER
FOUR
4.0 Results 23
CHAPTER
FIVE
5.0 Discussion,
Conclusion and Recommendation 27
5.1 Discussion
27
5.2 Conclusion 28
5.3 Recommendation 28
References
LIST OF TABLES
|
S/N
|
TITLE
|
PAGE NO
|
|
1
|
Occurrence
of E. coli among the Farm Animals
|
24
|
|
2
|
Morphological and Biochemical Characteristics of E. coli
|
25
|
|
3
|
Antibiotic Susceptibility Pattern of the Test Isolates
|
26
|
CHAPTER ONE
1.0 INTRODUCTION
Antibiotic
usage is possibly the most important factor that promotes the emergence,
selection and dissemination of antibiotic-resistant microorganisms in both
veterinary and human medicine (Daniels et
al., 2009). This acquired resistance occurs not only in pathogenic bacteria
but also in the endogenous flora of exposed individuals (animals and humans).
In intensively reared food animals, antibiotics may be administered to whole
flocks rather than individual animals, and antimicrobial agents may be continuously
fed to food animals such as poultry, goats, and cattle as growth promoters.
Therefore, the antibiotic selection pressure for bacterial drug resistance in
the animal is high and invariably their faecal flora contains a relatively high
proportion of resistant bacteria (Whitworth et
al., 2008).
Antibiotic
resistance among microorganisms is a major problem, both in human and livestock
industry. And the problem is usually attributed to unregulated and inappropriate
use of antibiotics (Lawson, 2008). It has been severally reported that
commensal Escherichia coli isolates from healthy animals like cattle,
swine as well as from humans play significant roles in the perpetration of drug
resistant pathogens and subsequent infections (Tian et al., 2012).
The
mechanism for spreading antibiotic resistance from animals to humans and vice
versa remains controversial. Colonization of the intestinal tract with
resistant Escherichia coli from chicken has been shown in human
volunteers and there is historical evidence that animals are a reservoir for E.
coli found in humans (Akwar et al.,
2008). Furthermore, spread of antibiotic resistance plasmids in E. coli from
chickens to human handlers or of antibiotics - resistant microorganisms from
animal to humans in various countries has been reported (Fang et al., 2008). Resistance has been found
in organisms common to both humans and animals, such as E. coli, Salmonella
spp., Campylobacter spp. and Enterococcus among others (Davis et al., 2009). Due to the intricate
balance of microflora of different habitats within the ecosystem, the transfer
of resistance genes among bacteria occupying different habitats has the potential
to occur frequently. Resistance genes may be transferred vertically among
bacteria of different genera and families or horizontally among different
bacterial species within the same genus or family (Call et al., 2008).
Widespread
reliance on antimicrobials in food animal production has resulted in a
considerable rise of antimicrobial-resistant strains of bacteria, complicating
the treatment of infectious diseases in livestock, companion animals, and
humans. This has led to important changes in the perceptions and priorities of
regulatory agencies with regard to antimicrobial usage, particularly the use of
antimicrobials as growth promoters and prophylactic agents. The selective
pressure from the use of antimicrobial agents at sub therapeutic levels in
dairy cattle could result in the selection of those strains that contain genes
for antimicrobial resistance (Call et al.,
2008).
Molecular
tools have been used to correlate animal associated pathogens with similar
pathogens affecting humans and to clearly demonstrate transferable resistant
genes carried by plasmid\s common to both animals and humans (Pitout et al., 2009). The possibility of
antibiotic resistance genes circulating among humans, animals and the
environment constitutes a direct threat to public health. This threat prompts
research into emerging resistance mechanisms, novel approaches to antimicrobial
efficacy and stringent control measures in the prudent use of antimicrobials in
animal medicine.
In
Nigeria livestock industry, the problem of occurrence of multidrug resistant E.
coli is becoming very rampart, because they are often encountered in
routine diagnoses of disease conditions from livestock brought for confirmatory
diagnosis in microbiology diagnostic units of some Tertiary Veterinary Teaching
Hospitals in Nigeria (unpublished data). Earlier in Nigeria, Ogunleye et al.
(2008), reported nineteen different multidrug resistant patterns to commonly
available antibiotic in E. coli isolated from some diseased poultry
samples from eleven poultry farms in Abeokuta, Ogun State, Nigeria. The 39 E.
coli were isolated from various organs like liver, lungs, kidneys, ovary,
intestine and colorectum of birds that died of septicaemic conditions. Each of
the E. coli isolates studied were resistant to between 5 and 12
com-monly used antibiotics such as nitrofurantoin, cefuroxime, norfloxacin,
cotrimoxazole, nalidixic acid, chloramphe-nicol, ampicilin, ofloxacin,
penincilin G, amoxylin, cloxa-cilin and ciprofloxacin (Ogunleye et al., 2008).
1.1 AIM
AND OBJECTIVES
To
determine the antibiotics resistance profile of E. coli isolated from farm animal in Umuahia metropolis, while the
specific objectives are;
· To
isolate E-coli strains from selected
farm animals
· To
determine the antibiotic sensitivity pattern of E. coli strains isolated from the farm animals
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