ABSTRACT
The evaluation of microbial succession of Cassava for Garri processing was carried out using grated or homogenized cassava for microbial analysis. The media used were Nutrient agar for total viable count, Violet red bile agar for enumeration of Enterobacteracea, Potatoe dextrose agar for enumeration of yeast and moulds and De, man Rogosa and sharpe agar for enumeration of Lactic acid bacteria. A serial dilution was done and Pour plate method was employed, Gram staining and bio-chemical tests were used for identification of the bacteria.The total aerobic plate count for the fermenting cassava ranged from 5.4 x109 C.F.U/ML to 2.5 x 103 C.F.U/ML, for yeast and mould count 5.2 x 109 C.F.U/ML to 6.5 x 103 C.F.U/ML and Lactic acid bacteria ranged from 9.8 x 109 C.F.U/ML to 4.4 x 103 C.F.U/ML and Enterobacteracea ranged from 5.2 x 109 to 6.5 x 103 C.F.U/ML respectively. The bacteria isolated from the fermenting cassava were Lactobacillus species, Aspergellus niger, Bacillus subtilis, Corynebacterium manihot, Leuconostoc mesenteroides, Geotrichum species, Saccharomyces cerevisea. An evaluation of microbial succession done revealed that Bacillus subtilis and Lactobacillus plantarum showed the highest acid producing ability, Bacillus subtilis and Klebsiella species contributed to the fermenting of the cassava The study concluded that a large number of microorganisms are involved in fermentation of cassava.
TABLE OF CONTENT
Certification i
Dedication ii
Acknowledgement iii
Table of content iv-vi
Abstract vii
CHAPTER ONE
1.0 INTRODUCTION 1
1.1
Justification of the Study 3
1.2
General Objectives 3
1.3
Aims and Objectives of the Study 3
CHAPTER TWO
2.0 LITERATURE REVIEW
Overview on Cassava (Manihot Esculenta Crantz)
4
2.2 Pest and Diseases 4
2.3 Economic Importance 5
2.4 Composition 5
2.5 Toxic Compounds in Cassava 6
2.6 Toxic Effects and Diseases Associated with
Cyanide Exposure 9
2.7 Diseases Related To Cassava Toxicity 11
2.8 Processing into Different Products 12
2.8.1 Garri: 12
2.8.2 Fufu: 13
2.8.3
Chickwangue: 14
2.9 Cassava Processing Techniques for Garri 14
2.9.1 Peeling 15
2.9.2 Grating and Chopping 15
2.9.3 Drying (Sun- And Oven-Drying) 15
2.9.4 Fermentation 16
2.9.4.1 Physical and Biochemical Changes
During Cassava Fermentation. 18
2.9.4.2 Biochemical Changes 19
CHAPTER THREE
3.0 MATERIALS AND METHODS
3.1 Study Area 22
3.2
Sterilization of Materials 22
3.3 Fermenting Procedure 22
3.4 Microbiological Population Studies 24
3.4.1 Media Used 23
3.5
Isolation of Bacteria and Yeast 23
3.6
Isolation Using Pour Plate Method 24
3.6.1 Sub-Culturing: 24
3.6.2 Identification of Bacterial Isolates 24
3.6.3 Identification of Fungal Isolates 24
3.7 Gram Staining 24
3.8 Biochemical Tests 25
3.8.1 Catalase Test: 26
3.8.2 Indole
Test 26
3.8.3 Citrate
Test 26
3.8.4 Oxidase Test 27
3.8.5
Carbohydrate Fermentation Test: 27
3.8.5 Motility Test: 27
3.9 Determination of Physiocochemical
Parameters 27
3.9.1 PH 28
3.9.2 Titrable Acidity 28
3.9.3 Cyanide Content 28
3.9.5 Fermentation Modulation 29
3.9.6 Effect of
Temperature 29
CHAPTER FOUR
4.0 RESULTS 30
4.1 Microbial Counts 30
4.2
Microbial Succession during Fermentation of Cassava for Garri Production 30
4.3
Identification of Organisms 31
4.9.2 Effect of PH, Titrable Acidity
(%) and Cyanide Content on Cassava Fermentation 39
4.9.3 Fermentation Modulation 39
Discussion 40
CHAPTER FIVE
5.1 Conclusion 44
References 45
CHAPTER ONE
1.0 INTRODUCTION
Cassava,
Manihot esculenta Crantz, is an important root crop in Africa,
Asia, South America and India Padmaja, (1995). Cassava is a staple food for at
least 500 million people in the tropics Bradbury, (2006) that provides
carbohydrates, or energy. It counts as a higher producer of carbohydrates per
hectare than the main cereal crops and can be grown at a considerably lower
cost Taiwo, (2006). The percentage of dry mater (starch content) in the
harvested root is an important criterion of quality both for human consumption
and for processing uses. The tuber consists of 64 - 87% starch depending on the
stage of the growth or maturity of the tuber but very limited quantities of
protein, fats, vitamins and minerals Alloys & Mings, (2006).
Additionally,
the roots contain considerable quantities of antinutrient factor cyanide. Cyanides
occur in cassava in the form of two cyanogenic glucosides, linamarin and
a small amount of methyllinamarin – lotaustralin – located inside the
plant cells together with a specific hydrolytic enzyme, linamarase, located
in the cell wall Bradbury, (2006). However, under normal conditions, they are
separated from the substrate. Any process that ruptures the cell walls will
bring the enzymes into contact with the glycosides and will thus release free
cyanide and reduce the glycosides‟ content of the final product. Based on the
amount of cyanides in the cassava roots, cassava has been classified into
“bitter” – and “sweet” – cassava. Thus the sweet varieties can be eaten boiled
while the bitter varieties have to be processed before it can be consumed Tewe,
(1992).
The
various fermentation processes have been broadly categorized into submerged
fermentation process, which involves the soaking of the roots under water as in
fufu production (retting), and the solid fermentation process, which does not
involve soaking as in the garri production (garifying) Oyewole, (2001). Traditionally, cassava roots
are processed in a number of ways that vary from region to region. The
processing methods involve several steps including peeling, soaking, grinding,
steeping in water or in the air to allow fermentation to occur, drying,
milling, roasting, steaming, pounding, and mixing in cold or hot water Taiwo, (2006).
A very popular processing method in Nigeria is grating of the peeled cassava
tubers and dewatering for 1-3 days during this period, fermentation occurs and
then the fermented product is sieved and roasted in a hot open pan (garified). The
different techniques of processing cassava roots have one common goal: the
reduction of cyanogenic compounds in order to obtain a safe food. All the
traditional processes for processing cassava permit the enzyme linamarase to
interact with cyanogenic compound to release HCN (hydrocyanic acid). The HCN
then dissolves in water or escapes into the air. However, it is often impossible
to remove all the cyanogenic compounds through processing.
Cassava
toxicity in humans is a well-documented problem. Cassava tubers vary widely in
their content of cyanogenic glycosides, although the normal range of cyanogenic
glycoside content is from 15 to 400 mg HCN/kg fresh weight. Cyanide doses up to
50 to 100mg/kg fresh peeled tuber are reported to be moderately poisonous to
adults whereas over 100mg HCN/kg fresh peeled tuber is dangerously poisonous Alloys
and Ming, (2006). Several diseases are associated with the consumption of
inadequately processed cassava roots, such as hypergoitre, tropical ataxic
neuropathy, epidemic spastic paraparensis Tewe, (1992) and konzo, Bradbury, (2006).
Sublethal doses of cyanogenic compounds are usually detoxicated in the body by
conversion to thiocyanate, a sulphur-containing compound with goitrogenic
properties if in excess, which is excreted in the urine Tewe, (1992). A chronic
overload of thiocyanate in conjuction with low iodine intake, however, results
in goiter and, in extreme cases, in cretinism in children (Oke, 1994).
Garri is a creamy white granular cassava based grit, produced from
fermented cassava by dewatering the grated cassava for 1-3days, it is a staple
food in many communities in Africa Akinrele et
al. (1985) and could be eaten as snacks with coconut, groundnut or sugar,
or it could be prepared into semi-solid meal with hot water called eba and
eaten with varieties of soup. Garri is by far, the most popular form in which
cassava is consumed in Nigeria and other African countries Ihekoronye and
Ngoddy. (1985).
1.1 Justification of the Study
Cassava
is a traditionally fermented food and
contributes substantially to the daily diets. These indigenous food is
locally prepared in small scale, in village homes; and its quality depends on
the skill of the household occupants, as inherited over years. The study will
focus on microbial evaluation of microbial succession and physiochemical
changes in fementation of cassava for garri.
1.2 General Objectives
To
evaluate the microbial succession and physiochemical changes in fermentation of
cassava for garri
1.3 Aims and Objectives of
the Study
To
isolate microorganisms from cassava during fermentation for garri processing
To
identify and characterize microorganisms from cassava during fermentation for
garri processing
To
determine physical parameters of the fermenting material (Cassava)
To determine chemical properties of the
fermenting material (Cassava)
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