EFFECT OF STORAGE PERIOD AND VARIETIES ON PROCESSED COCOYAM (COLOCASIA ESCULENTA) BASED FOODS (ACHICHA AND MPOTO)

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ABSTRACT

An experimental investigation, using three varieties of Colocasia esculenta was conducted. Sun-dried cocoyam corms (achicha) and leaves (mpoto) are invaluable sources of nutrients, which are consumed mainly in the South Eastern Nigeria. This study therefore, aimed at evaluating the effect of processing and storage of achicha and mpoto for a period of three months on chemical, functional, physicochemical properties, microbiological and sensory evaluation. The sun-dried cocoyam corms (achicha) and leaves (mpoto) were produced from matured cocoyam. The proximate composition of achicha and mpoto samples showed a increase of 3.93 to 5.77% and 14.7 to 16.83% in crude protein respectively as storage period progressed. The functional properties of achicha samples did not differ significantly (p>0.05) in the parameters considered. Potassium content was most abundant both in achicha (285.77 to 405.87mg/100g) and mpoto (325.87 to 485.52mg/100g) samples in the mineral composition. Vitamin composition of achicha and mpoto samples showed a increase of (2.47 to 4.14mg/100g) and (8.61 to18.46mg/100g) in vitamin C content respectively as storage period progressed. Alkaloid levels of both achicha and mpoto ranged from 1.19 to 1.63mg/100g and 1.52 to 1.85mg/100g respectively. Sugar and starch contents of achicha samples ranged from 1.94 to 4.15% and 51.64% to 65.06% respectively. Total viable counts (TVC) of achicha and mpoto samples ranged from 1.60 x 104 to 3.40 x 104 and 1.20 x 104 to 2.70 x 104 respectively. Total fungal counts (TFC) of achicha and mpoto ranged from 0.30 x 104 to 1.70 x 104 and 0.1 x 104 to 1.00 x 104 respectively. The microbiological counts of samples increased with increase in the storage time. Achicha meal and mpoto soup did not show any significant (p>0.05) difference in the sensory evaluation.

TABLE OF CONTENTS

Title page i

Declaration ii

Certification page iii

Dedication iv

Acknowledgement v

Table of contents vi

List of Tables ix

List of Figures x

List of Plates xi

Abstract xii

CHAPTER 1: INTRODUCTION 1

1.1 Background Information 1

1.2 Statement of the Problem 4

1.3 Objectives of the study 4

1.4 Justification of the study 5

CHAPTER 2: LITERATURE REVIEW

2.1 Origin of Colocasia esculenta 6

2.2 Spoilage of Cocoyam 6

2.3 Storage of Cocoyam 7

2.4 Factors Affecting Storability of Roots and Tubers 8

2.5 Physiological Factors. 9

2.5.1 Respiration 9

2.5.2 Dormancy and Sprouting 9

2.5.3 Skin permeability 10

2.5.4 Temperature effect on dormancy 10

2.5.5 Damage by Extremes of Temperature 11

2.6 Nutrition and other Importance of Taro 11

2.6.1 Health benefits 12

2.6.2 Vitamins 15

2.6.3 Vitamin C 17

2.7 Phytochemicals 18

2.7.1 Phenolic Acids 21

2.8 Anti-nutritional factors limiting utilization of taro 21

2.8.1 Mucilage 22

2.8.2 Oxalic acid and oxalates 22

2.8.3 Protease (trypsin and chymortrypsin) inhibitors 23

2.8.4 Lectins 23

2.8.5 Alpha- amylase inhibitors 24

2.9 Processing of taro into different products 24

2.9.1 Colocasia esculenta flour 25

2.9.2 Uses 26

CHAPTER 3: MATERIALS AND METHODS 28

3.1 Sample collection 28

3.2 Preparation of samples 28

3.2.1 Preparation of achicha meal and mpoto soup 33

3.3 Proximate Analysis 41

3.3.1 Determination of moisture content 41

3.3.2 Determination of total ash content 42

3.3.3 Determination of crude protein 42

3.3.4 Determination of Crude Fibre 43

3.3.5 Determination of fat content 44

3.3.6 Determination of Carbohydrate 45

3.3.7 Determination of Dry matter 45

3.4 Functional Properties 46

3.4.1 Determination of Bulk Density 46

3.4.2 Determination of Swelling Index 46

3.4.3 Determination of water/oil absorption capacity 47

3.4.4 Determination of Wettability 48

3.4.5 Determination of Gelation capacity 49

3.4.7 Determination of foam stability 49

3.4.8 Determination of Foam Capacity 49

3.4.9 Determination of Viscosity 50

3.4.10 Determination of pH 50

3.5 Mineral Analysis 50

3.5.1 Extraction by wet-acid Digestion for multiple nutrients 51

3.5.2 Determination of Heavy metals by the Atomic Absorption

Spectrophotometer (AAS) 51

3.5.3 Determination of phosphorus by the Molybdate yellow

Method using Spectrophotometer 52

3.5.4 Determination of Potassium and Sodium using the

Flame photometer 52

3.5.5 Determination of Calcium and Magnesium by the Versenate

EDTA Complexometric 52

3.6 Phytochemical Analysis 53

3.6.1 Determination of Alkaloid Content 53

3.6.2 Determination of Tannin content 53

3.6.3 Determination of saponins content 54

3.6.4 Determination of flavonoid content 55

3.6.5 Determination of polyphenol 56

3.6.6 Determination of oxalate 57

3.6.7 Determination of Phytate 58

3.7 Vitamin Analysis 59

3.7.1 Determination of Vitamin A 59

3.7.2 Determination of Vitamin B₁ (Thiamin) 60

3.7.3 Determination of Vitamin B₂ (Riboflavin) 60

3.7.4 Determination of Vitamin B₃ (Niacin) 61

3.7.5 Determination of Vitamin C (Ascorbic acid) 62

3.8 Carbohydrate Analysis 63

3.8.1 Determination of Amylose content 63

3.8.2 Determination of Starch content 64

3.8.3 Determination of Sugar content 64

3.9 Microbiological Analysis 65

3.9.1 Isolation of microorganism from the samples, characterization

and culturing of the samples 65

3.9.2 Purification of isolate 65

3.9.3 Characterization of isolates (bacteria) 66

3.9.4 Characterization of isolates (fungi) 66

3.9.5 Determination of the microbial load 66

3.9.6 Counting of colonies 66

3.9.7 Calculation of microbial load (cfu/g) 67

3.10 Sensory Evaluation 67

3.11 Statistical Analysis 67

CHAPTER 4: RESULTS AND DISCUSSION

4.1: Proximate and dry matter Composition of Achicha stored from

Zero to three Months (%) 68

4.1.1 Moisture content 68

4.1.2 Ash content 66

4.1. 3 Crude Protein 66

4.1.4 Crude Fat 67

4.1.5 Crude Fibre Content 67

4.1.6 Carbohydrate Content 68

4.1.7 Dry matter 68

4.2: Functional Properties of Achicha Stored for Three Months 73

4.2.1 Bulk Density (g/ml) 73

4.2.2 Swelling index (ml) 74

4.2.3 Water absorption capacity (WAC) (ml/g) 75

4.2.4 Oil absorption capacity (ml/g) 77

4.2.5 Wettability (sec) 78

4.2.6 Gelation capacity (g/5ml) 78

4.2.7 Gelation Temperature (^oC) 79

4.2.8 Foam Stability (%) 79

4.2.9 Foam Capacity (%) 80

4.2.10 Viscosity (mpa) 81

4.2.11 pH 82

4.3: Mineral Composition of Achicha stored forThree Months

(mg/100g) 84

4.3.1 Calcium (Ca) content 84

4.3.2 Sodium (Na) content 85

4.3.3 Magnesium (Mg) content 85

4.3.4 Potassium (K) content 85

4.3.5 Phosphorous (P) content 86

4.3.6 Iron (Fe) content 87

4.3.6 Zinc (Zn) content 87

4.3.7 Manganese (Mn) content 88

4.3.8 Iodine (I) Content 88

4.4: Vitamin Composition of Achicha from Zero to Three Months

(mg/100g) 90

4.4.1 Total carotene (ug/100g) content 90

4.4.2 B1 (Thiamin) mg/100g content 90

4.4.5 B2 (Riboflavin)Mg/100g content 90

4.4.4 B3 (Niacin) mg/100g content 91

4.4.5 Vitamin C (Ascorbic Acid) mg/100g content 91

4.4.6 Vitamin E (Tocopherol) mg/100g content 91

4.5: Phytochemical Composition of Achicha stored for Three Months

mg/100g) 93

4.5.1 Alkaloid content 93

4.5.2 Oxalate content 93

4..5.3 Phytate content 93

4.5.4 Saponin content 94

4.5.5 Flavonoid Content 94

4.5.6 Polyphenol content 94

4.5.7 Tannin content 94

4.6: Carbohydrate Analysis of Achicha stored for Three Months (%) 97

4.6.1 Amylose content 97

4.6.2 Amylopectin content 97

4.6.3 Starch content 97

4.6.4 Sugar content 98

4.7: Total Viable Count (TVC) of Achicha stored for Three Months

(cfu/g) 100

4.8: Total Fungal Count (TFC) of Achicha stored for Three

Months (cfu/g) 102

4.9: Sensory Evaluation of Achicha from Three Varieties

of Colocasia esculenta 104

4.9.1 Aroma 104

4.9.2 Appearance 104

4.9.3 Texture 105

4.9.4 Taste 105

4.9.5 Overall acceptability 105

4.10: Proximate and Dry Matter Compositions of Mpoto stored for

Three Months (%) 107

4.10.1 Moisture content 107

4.10.2 Dry Matter Content 107

4.10.3 Ash Content 107

4.10.4 Crude Protein content 107

4.10.5 Crude Fat Content 108

4.10.6 Crude Fibre content 108

4.10.7 Carbohydrate Content 109

4.11: Mineral Composition of Mpoto stored for Three Months

(mg/100g) 111

4.11.1 Calcium (Ca) content 111

4.11.2 Sodium (Na) Content 111

4.11.2 Magnesium (Mg) Content 112

4.113 Potassium (K) Content 112

4.11.4 Phosphorus (P) Content 112

4.11.5 Iron (Fe) Content 112

4.11.6 Zinc (Zn) Content 113

4.11.7 Manganese (Mn) Content 113

4.11.7 Iodine (I) Content 113

4.12: Vitamin Composition of Mpoto stored for Months (mg/100g) 115

4.12.1 Total Carotene (ug/100g) Content 115

4.12.2 B1 (Thiamin) mg/100g Content 115

4.12.3 B2 (Riboflavin) mg/100g Content 115

4.12.4 B3 (Niacin) mg/100g content 116

4.12.5 Vitamin C (Ascorbic Acid) mg/100g Content 116

4.12.6 Vitamin E (Tocopherol) mg/100g content 117

4.13 Phytochemical Composition of Mpoto stored for Three Months

(mg/100g) 119

4/13.1 Alkaloid Content 119

4.13.2 Oxalate Content 119

4.13.3 Phytate Content 119

4.13.4 Saponin Content 119

4.13.5 Flavonoid Content 120

4.13.6 Polyphenol Content 120

4.13.7 Tannin Content 120

4.14 Total Viable Count (TVC) of Mpoto stored for Three Months

(cfu/g) 122

4.15: Total Fungal Count (TVC) of Mpoto stored for Three Months

(cfu/g) 124

4.16: Sensory Evaluation of Mpoto Soup from Three Varieties of

Colocasia esculenta 126

4.16.1 Aroma 126

4.16.2 Appearance 126

4.16.3 Texture 126

4.14.4 Taste 127

4.16.5 Overall acceptability 127

CHAPTER 5: CONCLUSION AND RECOMMENDATION

5.1 Conclusion 129

5.2 Recommendation 130

REFERENCES 131

APPENDICES 147

Appendix 1 147 Appendix 2 148

Appendix 3 149

Appendix 4 150

LIST OF TABLES

Table 4.1: Proximate and dry matter Compositions of Achicha stored for

Three Months (%) 72

Table 4.2: Functional Properties of Achicha stored for Three Months 83

Table 4.3: Mineral Composition of Achicha stored for Three Months (mg/100g) 89

Table 4.4: Vitamin Composition of Achicha stored for Three Months 92

Table 4.5: Phytochemical Composition of Achicha stored for Three Months 96

Table 4.6: Carbohydrate Analysis of Achicha stored for Three Months (%) 99

Table 4.7: Total Viable Count (TVC) of Achicha stored for Three Months (cfu/g) 101

Table 4.8: Total Fungal Count (TFC) of Achicha stored for Three Months (cfu/g) 105

Table 4.9: Sensory Evaluation of Achicha from Three Varieties of

Colocasia esculenta 106

Table 4.10: Proximate and Dry Matter Compositions of Mpoto stored for

Three Months (%) 110

Table 4.11: Mineral Composition of Mpoto stored for Three Months (mg/100g) 114

Table 4.12: Vitamin Composition of Mpoto stored for Three Months 118

Table 4.13: Phytochemical Composition of Mpoto stored for Three Months 121

Table 4.14: Total Viable Count (TVC) of Mpoto stored for Three Months (cfu/g) 123

Table 4.15: Total Fungal Count (TFC) of Mpoto stored for Three Months (cfu/g) 125

Table 4.16: Sensory Evaluation of Mpoto Soup from Three Varieties of

Colocasia esculenta 128

LIST OF FIGURES

Figure 1: The Flow chart of the production of achicha 30

Figure 2: The Flow chart of the production of mpoto 32

LIST OF PLATES

Plate 1: Colocasia esculenta corms/cormel 29

Plate 2: Colocasia esculenta leaves 31

Plate 3: Achicha meal 36

Plate 4: mpoto soup 37

LIST OF EQUATIONS

Equation 2.5.1: Respiration 9

Equation 3.3.1: Determination of moisture content 38

Equation 3.3.2: Determination of total ash content 39

Equation 3.3.3: Determination of crude protein 40

Equation 3.3.4: Determination of Crude Fibre 41

Equation 3.3.5: Determination of fat content 42

Equation 3.3.6: Determination of carbohydrate 42

Equation 3.4.1: Determination of bulk density 43

Equation 3.4.2: Determination of Emulsification Capacity 43

Equation 3.4.3: Determination of Swelling Index 44

Equation 3.4.4: Determination of water/oil absorption capacity 44

Equation 3.4.7: Determination of foam stability 46

Equation 3.4.8: Determination of Foam Capacity 46

Equation 3.6.1: Determination of Alkaloid Content 50

Equation 3.6.2: Determination of Tannin content 51

Equation 3.6.3: Determination of saponins content 52

Equation 3.6.4: Determination of flavonoid content 52

Equation 3.6.5: Determination of polyphenol 53

Equation 3.6.6: Determination of oxalate 54

Equation 3.6.7: Determination of Phytate 55

Equation 3.7.1: Determination of Vitamin A 56

Equation 3.7.2: Determination of Vitamin B₁ (Thiamin) 57

Equation 3.7.3: Determination of Vitamin B₂ (Riboflavin) 58

Equation 3.7.4: Determination of Vitamin B₃ (Niacin) 59

Equation 3.7.5: Determination of Vitamin C (Ascorbic acid) 59

Equation 3.8.1: Determination of Amylose content 60

Equation 3.8.2: Determination of Starch content 61

CHAPTER 1

INTRODUCTION

1.1 BACKGROUND INFORMATION

In the region of West and Central Africa, the term cocoyam is attributed to two members of the Araceae family, namely, Colocasia esculentum (L.) Schott and Xanthosoma sagittifolium (L.) Schott, in the sub family Colocasioideae according to Dahlgren et al. (1985). Aguegui et al. (1992) reported, they are staple foods for many people in developing countries of Africa, Asia and the Pacific. Cocoyam (Colocassia and Xanthosoma spp.) is a stem tuber that is widely grown in the tropical regions of the world (Eze and Okorji, 2003). Three other genera: Alocasia, Amorphophallus and Cyrotosperma are common in the tropical regions of Pacific (Okaka, 1997).

This plant ranks as the fourteenth most consumed vegetable worldwide, and is grown widely in the tropical and sub-tropical countries (FAO, 1986). More so, it is third in importance after cassava and yam among the root and tuber crops consumed in Nigeria as reported by Udealor et al. (1996) and Onwueme (1978).

About 60% of the World’s cocoyam production (5.7 million ton) is in Africa and majority of the remaining 40% in Asia and the Pacific (Mitra et al., 2007). Eze and Okorji (2003) also reported that Nigeria is the largest producer of cocoyam in the world, accounting for about 40% of the total world output.

According to Manner and Taylor (2010) in other parts of the world, species of Colocasia are often referred to as taro, while cocoyam or tannia is used for species of Xanthosoma. In the Pacific Island countries where taro is widely cultivated and consumed, two botanical varieties of Colocasia have been identified as C. esculenta var. esculenta, many times called dasheen, and C. esculanta Var. esculenta, frequently called eddoe. Purseglore (1972) stated that dasheen varieties have very big central (middle) corms with suckers and or stolons, whereas eddoes have a relatively small central corm and a large number of smaller cormels. Colocasia is believed to have originated in the Indo – Malaysian region, from where it spread into the pacific Islands, the Eastern Mediterranean and finally to Africa (Kay, 1987).

Cocoyam without any doubt is an important food crop across many countries in South Saharan region, specifically in Nigeria, Ghana and Cameroon. Cocoyam is a major vegetable and source of income to farming household in Ghana. It is referred to as the third important staple root crop after yam and cassava in Nigeria and provides a cheaper yam replacement, especially during periods of food scarcity or insufficient food supply (Onyeka, 2014).

According to Wang (1983) cocoyam is rich in carbohydrates with nutritional value comparable to potato. Also cocoyam is superior to cassava and yam in the possession of higher protein, mineral and vitamin contents as well as easily digestible starch (Parkinson, 1984, Splittstoesser et al, 1973). Cocoyam also contains higher noticeable quantities of essential minerals (Ca, Mg and P) than cassava and yam. It is to a great extent recommended for diabetic patients, the aged, children with allergies and for persons with intestinal disorders (Plucknett, 1970). The corms and cormels of cocoyam may be processed by boiling, baking or frying in oil. They may also be processed into different food products in many parts of West and Central Africa.

All major parts of cocoyam (corm, cormel and leaves) are edible. The young leaves are nutritious spinach-like vegetable, which supplies a lot of minerals and vitamins. This is particularly a major vegetable and source of income to farming household in Ghana.

The leaves from Taro (Colocosia esculenta) are rich in vitamins and minerals. They are suitable sources of thaimine, riboflavin, iron, phosphorus and zinc and a very good source of vitamin B6, vitamin C, niacin, and exceptionally in the leaves, also it is highly perishable that is it has high content of water. Leaves of new cocoyam are also used in pig-feeding because of its nutritional benefits (Agrid, 2006). Preliminary investigations have revealed that most vegetables are good source of antioxidants, but some are definitely better than others. When it comes to vitamins, minerals, carotenoids and cruciferous phytonutrients, which are all virtually important to good health, the most potent vegetable are dark green leafy vegetables, Green leafy vegetables are greatly used for food in many countries of the world; they are good sources of β-Carotene, ascorbic acid, minerals and dietary fibre (Moshaand and Gaga, 1999). However, dark vegetables are more nutritious than those with lighter or yellowish leaves. They are in large amount shortly after rainy season but become insufficient during the dry season, these vegetables could be harvested at all stages in the process of growth or could be consumed fresh, semi- processed or processed forms (Moshaand and Gaga, 1999).

Agrid (2006) reported cocoyam is a well-known food plant, which has a long history of cultivation. Its corms are important source of starch. They may also be cut up and boiled in curries or fried to make crispy chips. The leaf stalks can also be eaten. The leaves which are seldomly used for food must be cooked. Every part of the raw cocoyam plant contains a toxic compound calcium oxalate, which must be destroyed through cooking before eating (Fafunso and Baser, 1987).

Achicha (dried cocoyam corms/cormels) is a pre-cooked, sun-dried cocoyam corms/cormels and it lends its name to the vegetarian dish made with it. Achicha does not only have enjoyable taste and satisfying but also low in calories. Achicha can be cooked in combination with fiofio (pigeon pea) or black beans (akidi oji), these are highly nutritional. Green leafy vegetables can also be added to it, for example, green amaranth, ugu and scent leaf. Dry fish is also added which is an optional ingredient.

Mpoto (dried cocoyam leaves) is a vegetable used in preparing soup delicacy. This is peculiar to the Igbo people of Eastern Nigeria.

1.2 STATEMENT OF PROBLEM

The cocoyam (Colocasia esculenta) is highly perishable root and leaves, crop as high as 40-60% post harvest losses have been found (Anaele and Nwawusi, 2008). Nwufo and Atu (1987) stated that microorganisms take the lead in post harvest rot. The high perishability of the harvested and stored cocoyam roots and leaves is a major barrier to the wider utilization of the crop and there is need to diversify the uses to enhance demand and increase the rate of turn over or sale of the product. Lack of adequate cocoyam processing technology inhibits production and processing. Over the years due to the high perishable nature of cocoyam local farmers had adopted sun-drying as a means of preserving the cocoyam. It becomes necessary to evaluate the effect of these processes and storage methods on the the overall quality of the cocoyam products.

1.3 OBJECTIVES OF THE STUDY

The main objective of this study is to evaluate the effect of storage period on the quality of cocoyam based products.

The specific objectives of this work are:

1. To produce achicha (dried cocoyam corms/cormels) and mpoto (dried cocoyam leaves)

2. To evaluate the proximate/dry matter compositions of achicha and mpoto for a period of three months storage.

3. To evaluate the functional properties of achicha for a period of three months storage.

4 To determine the mineral composition of achicha and mpoto for a period of three months storage.

5 To evaluate the vitamins of achicha and mpoto for a period of three months storage.

6 To determine the phytochemicals composition present in achicha and mpoto for a period of three months storage.

7 To investigate the carbohydrate component of achicha for a period of three months storage.

8 To determine the microbiological load of achicha and mpoto for a period of three months storage.

9 To evaluate the sensory properties of achicha and mpoto after a period of 3 months.

1.4 JUSTIFICATION

Processing of cocoyam corms/cormels and leaves into more shelf-stable dry products such as achicha and mpoto will reduce post harvest losses of cocoyam, provide a market for small scale farmers, and diversify the uses of cocoyam. Evaluation of the quality and shelf stability of the achicha and mpoto would give confidence to the producers and consumers of these products.

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