EFFECTS OF PROCESSING ON NUTRIENT COMPOSITION, PHYTOCHEMICALS AND CAROTENOID PROFILE OF TWO CULTIVARS OF PTEROCARPUS SANTALINOIDES

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ABSTRACT

The effects of processing on nutrient composition, phytochemicals and carotenoid profile of two cultivars of Pterocarpus santalinoides were investigated. The tender leaves of Pterocarpus santalinoides was selected, washed, surface air dried, sliced at 1.5 m, then divided into four portions, raw, oven dried (500C for 1h 20 min), sautéed (500g/20ml) of fat and Blanched (1000C) for 3 min. The proximate composition, vitamins, minerals, and phytochemicals were determined according to standard methods. Carotenoid profile was determined using HPLC. The moisture content ranged from 36.84 – 76.66 %, crude protein; 12.68 – 16.42 %; Oven drying and sautéing improved the crude protein content, Ash content ranged from 1.84 to 4.15 % and was improved by oven drying. Crude fibre was moderately present in the cultivars (1.95 – 3.72 %). Oven dried Afu had high crude fibre (3.72%) than other samples (p<0.05). The Pterocarpus santalinoides cultivars are good sources of energy (81.18 – 248 K/J. Vitamin B6 (41.07 – 94.17), Afu blanched had the highest quantity of vitamin B6 (94.17 mg/100g) Pro-vitamin A content ranged from 8.95 – 243.72 µg/g and was in the highest amongst in sautéed Afu (243.72 µg/g). Vitamin C value ranged from 13.42 to 20.39 mg/100g. Raw Osw was higher in vitamin C (20.39 mg/100g), vitamin B1, B2, B3, B9 and vitamin E were in trace amount. Iodine content ranged from 45.99 to 63.33 mg/100g was significantly higher (p<0.05) in Raw Osw (63.33 mg/100g). Processing moderately reduced the iodine content. Potassium content ranged from 40.00 to 59.50 mg/100g. Osw oven dried sample had the highest iodine content (59.50 mg/100g). Magnesium content ranged from 42.12 to 44.90 mg/100g. Oven drying and sautéing improved magnesium in Osw significantly (p<0.05) (44.90 %). Iron was present in appreciable amounts (6.20 – 7.75 mg/100g). Processing did not have any significant effect on the iron content of the cultivars. Calcium (3.50 – 4.09 mg/100g) was moderately available; oven drying and sautéing significantly improved the iron content among others (4.08 and 4.09 %). Zinc (1.10 –1.29) was in trace amount. Phytochemicals analyzed were in trace amount except alkaloid (3.38 –7.73 mg/100g), oven dried and sautéed samples (4.62 and 4.52 %) respectively moderately reduced the alkaloid but blanching drastically reduced it (3.38%). The total β carotene ranged from 8.08 to 232 µg/g. Sautéing improved the total β carotene; sautéed Afu had the highest value (232.46%). Trans β carotene was present in measurable concentration (3.97 –108.15 µg/g), sautéed Afu and Osw (108.15, 102.75 µg/g) had the highest values. 13-cis β carotene was in appreciable concentration (2.58 – 86.31 µg/g). Sautéed Afu had the highest 13-cis β carotene content (86.31µg/g) significantly. - Carotene (1.66 – 23.83 µg/g) was in trace amount, but sautéing significantly improved it to 23.83, 22.53 µg/g. The chromatogram showed (4 – 7) major peaks and several minor peaks that were not identified due to lack of standard. Afu cultivar had more carotenoid than Osw cultivar. Sautéing was the best method for enhancing the carotenoid profile.

TABLE OF CONTENTS

Cover Page i

Title Page ii

Declaration iii

Certification iv Dedication v

Acknowledgements vi

Table of Contents vii

List of Tables xii

List of Figures xiii

List of Plates xiv

Abstract xv

CHAPTER 1: INTRODUCTION

1.1 Background of the Study 1

1.2 Statement of Problem 5

1.3 Objective of the Study 7

1.4.1 Specific Objectives 7

1.4.2 Justification 7

CHAPTER 2: LITERATURE REVIEW

2.1 History of Nturukpa (Pterocarpus santalinoides) 9

2.1.1 Vegetables and their uses 10

2.1.2 Constituents of green leafy vegetables 11

2.1.3 Underutilized vegetables 11

2.1.4 Importance of underutilized vegetables 13

2.1.5: Uses of Pterocarpus Santalinoides 13

2.1.6 Constraints that render a few vegetables underutilized 14

2.2 Processing of Green Leafy Vegetables 16

2.2.1 Blanching 17

2.2.2 Drying and dehydration (oven drying) 17

2.2.3 Sauteeing 18

2.3 Vitamin 18

2.3.1 Vitamin A 19

2.3.2 Bioavailability of vitamin A 22

2.3.3 Vitamin B₆ 23

2.3.3.1 Bioavailability of vitamin B₆ 23

2.3.4. Vitamin C 24

2.3.4.1 Bioavailability of vitamin C 25

2.3.5 Vitamin E 26

2.3.5.1 Bioavailability of vitamin E 28

2.4 Minerals 28

2.4.1 Classification of minerals 29

2.4.1.1 Classification of trace elements 30

2.4.1.2 Role of trace elements 30

2.4. 1.3 Role of major, minor and trace elements 31

2.5.1 Sodium 31

2.5.2 Potassium 32

2.5.2.1 Potassium bioavailability 34

2.5.3 Calcium 35

2.5.3.1 Bioavailability of calcium 36

2.5.4 Magnesium 36

2.5.4.1 Bioavailability of magnesium 37

2.5.5 Zinc 38

2.5.5.1 Bioavailability of zinc 39

2.5.6 Manganese 40

2.5.7 Iodine 41

2.5.7.1 Bioavailability of iodine 41

2.5.8 Selenium 42

2.5.9 Iron 43

2.5.9.1 Bioavailability of iron 44

2.6 Anaemia 45

2.7 Phytochemicals 47

2.7.1 General functions of phytochemicals 48

2.7.2 Phenols 49

2.7.2.1 Biological function of phenols 50

2.7.2.2 Anti-Nutritional effects of phenols 51

2.7.3 Saponins 51

2.7.3.1. Natural functions of saponins 52

2.7.3.2 Anti-Nutritional effects of saponins 53

2.7.4 Oxalate 53

2.7.4.1 Biological Function of Oxalate 54

2.7.4.2 Anti-Nutritional Effects of Oxalate 54

2.7.5 Cardiac Glycosides 55

2.7.5.1 Biological function of cardiac glycosides 55

2.7.5.2 Anti-Nutritional effects of cardiac glycosides 56

2.7.6 Tannins 56

2.7.6.1 Biological function of tannins 57

2.7.6.2 Anti-Nutritional effects of tannins 58

2.7.7 Phytate 58

2.7.7.1. Natural functions of phytic acid 59

2.7.7.2 Anti-Nutritional effects of phytic acid 60

2.7.8 Alkaloids 60

2.7.8.1 Biological function of alkaloids 61

2.7.8.2 Anti-Nutritional effects of alkaloids 62

2.7.9 Flavonoids 62

2.7.9.1 Biological function of flavonoids 64

2.7.9.2 Anti-Nutritional effects of flavonoids 64

2.7.10 Haemagglutinin 65

2.7.10.1 Biological function of plant haemaglutinin 65

2.7.10.2 Anti-Nutritional effects of plant haemaglutin 66

2.8 Carotenoids and its sources 66

2.8.1 Classification of carotenoids 68

2.8.2 Types of carotenoids 69

2.8.2.1 Carotenes 73

2.8.2.2 Lycopene 74

2.8.2.3 Uses and application of carotenoids in food and nutraceutical industry 75

2.8.3 Factors implicated in the cardiovascular disease 76

2.8.4 Biosynthesis of carotenoids and its pathway 76

2.8.5: The role of carotenoid as an antioxidant, pro-vitamin A, and it’s

Mechanism of action. 79

2.8.6 The relevance of carotenoids in food industry 83

CHAPTER 3: MATERIALS AND METHODS

3.1 Sample Source 85

3.2 Sample Preparation 85

3.3 Determination of Proximate Composition 89

3.3.1 Determination of moisture content 89

3.3.2 Determination of crude protein 89

3.3.3 Determination of ash content 90

3.3.4 Crude fat content determination 90

3.3.5 Determination of crude fibre 91

3.3.6 Determination of carbohydrate content 92

3.3.7 Determination of energy value 92

3.4. Determination of Vitamin Composition 92

3.4.1 Determination of vitamin B₁ 92

3.4.2 Determination of riboflavin content (B₂) 92

3.4.3 Determination of vitamin B₃ 93

3.4.4 Determination of B₆ 94

3.4.5 Vitamin C content determination. 94

3.4.6 Determination of vitamin E content 95

3.5. Determination of Minerals 95

3.5.1 Determination of calcium and magnesium 95

3.5.2 Determination of trace element 96

3.5.3 Determination of iodine value 97

3.6. Determination of phytochemicals 98

3.6.1 Determination of tannin content 98

3.6.2 Determination of alkaloid content 99

3.6.3 Determination of flavonoid content 99

3.6.4 Determination of phytate content 100

3.6.5 Determination of oxalate content 101

3.6.6 Hydrogen cyanide determination 102

3.7. Protocol for Carotenoid Analysis of Vegetables 102

3.7.1 Sample extraction 103

3.7.2 Identification of the carotenoid 104

3.8 Statistical Analysis

CHAPTER 4: RESULT AND DISCUSSION

4.1 Morphological and Description of Pterocarpus santalinoides Leaves 105

4.2 Effect of Processing Methods on the Proximate Composition of Two

Cultivars of Pterocarpus santalinoides 107

4.2.1 Moisture content 110

4.2.2 Crude protein 111

4.2.3 Crude fat 111

4.2.4 Fibre content 112

4.2.5 Ash 113

4.2.6 Carbohydrate 114

4.2.7 Energy value 115

4.3 Effect of Processing Methods on the Vitamin Content of Two

Cultivars of Pterocarpus santalinoides. 116

4.3.1 Vitamin B₁ 118

4.3.2 Vitamin B₂ 119

4.3.3 Vitamin B₃ 120

4.3.4 Vitamin B₆ 121

4.3.5 Vitamin B₉ 121

4.3.6 Pro-vitamin A 122

4.3.7 Vitamin C 122

4.3.8 Vitamin E 124

4.4 Effect of Processing Methods on Mineral Content of Two Cultivars of

Pterocarpus santalinoides. 127

4.4.1 Iron 129

4.4.2 Magnesium 130

4.4.3 Zinc 131

4.4.4 Calcium 132

4.4.5 Selenium 133

4.4.6 Potassium 134

4.4.7 Iodine 135

4.5 Effect of Processing on the Phytochemical Content of Pterocarpus

santalinoides 137

4.5.1 Steriod 139

4.5.2 Phenol 139

4.5.3 Saponin 140

4.5.4 Oxalate 140

4.5.5 Cyangenic glycosides 141

4.5.6 Anthocyanin 142

4.5.7 Tannin 142

4.5.8 Phytate 144

4.5.9 Alkaloid 144

4.5.10 Flavonoid 146

4.6 Effect of Processing on the Carotenoid Profile of Two Cultivars of

Pterocarpus santalinoides 148

4.6.1 α-carotene 150

4.6.2 13-cis-β-carotene 151

4.6.3: Trans β-carotene 152

4.6.4: 9-cis-β carotene 153

4.6.5: Total β-carotene 154

CHAPTER 5: CONCLUSION AND RECOMMENDATION

5.1 Conclusion 161

5.2 Recommendation 162

References 163

Appendices

LIST OF TABLES

2.1 The Medicinal Value of Some Alkaloid 61

2.2 Carotenoid Types, Examples, Sources and Medicinal Properties 68

4.1 Effect of Processing on the Proximate Composition of Two

Cultivars of Pterocarpus santalinoides 109

4.2 Effect of Processing Methods on the Vitamin Composition of

Two Cultivars of Pterocarpus santalinoides 117

4.3 Effect of Processing Methods on Mineral Composition of Two

Cultivars of Pterocarpus santalinoides 128

4.4 Effects of Processing on Phytochemical Composition of Two

Cultivars of Pterocarpus santalinoides 138

4.5 Effect of Processing on Carotenoid Profile of Two Cultivars

of Pterocarpus santalinoides 149

LIST OF FIGURES

2.1 Pterocarpus santalinoides (Nturukpa leaves). 9

2.2 Phenols Other Names: Carbolic Acid, Benzenol,

Phenylic Acid 50

2.3 Chemical Structure of the Saponin 52

2.4 The Structure of the Oxalate Anion. 53

2.5 The Chemical Structure of Oleandrin, Toxic Cardiac Glycosides 55

2.6 Tannic Acid 57

2.7 Molecular Structure of Phytic Acid 59

2.8 The Nicotine Molecule 61

2.9 Molecular Structure of the Flavone Backbone. 63

2.10 Chemical Structure of all Major Carotenoids 72

2.11 Biosynthetic Pathway of Carotenoids in Plants 78

2.12 Biosynthetic Contents of Biosynthesis 79

3.1a Pterocarpus santalinoide, (Avuo leaves) 86

3.1b Pterocarpus santalinoides (Oselukwu leaves). 87

3.2 Preparation of Pterocarpus santalinoides Samples 88

4.2.a Carotenoid Profile of Raw Pterocarpus santalinoides

(Afu cultivar). 155

4.2.b Carotenoid Profile of Sautéed Pterocarpus santalinoides

(Afu cultivar) 156

4.2.c Carotenoid profile of Raw Pterocarpus santalinoides

(Osw cultivar). 157

4.2.d Carotenoid Profile of Sautéed Pterocarpus santalinoides

(Osw cultivar). 158

LIST OF PLATES

1 Avuo (Oven drying) 106

2 Oselukwu (Oven drying) 106

3 Avuo (Blanching) 106

4 Oselukwu (Blanching) 106

5 Avuo (Sautéing) 107

6 Oselukwu (Sautéing) 107

CHAPTER 1

INTRODUCTION

1.1 BACKGROUND OF THE STUDY

The role of diets and sustenance as determinants of persistent sicknesses is all around recorded (Thiam et al., 2006). The expense of these illnesses has brought about friendly pain, loss of efficiency and financial weight on wellbeing. The variables adding to the quick change in sickness design incorporate urbanization, change in diets and reception of a more westernized way of life because of monetary turn of events and market globalization (WHO/FAO, 2003). This has brought about the relinquishment of native food sources that are wealthy in supplements and wellbeing ensuring parts. Vegetables are agrarian items which are significant wellsprings of defensive food varieties that are profoundly valuable for the support of good wellbeing and avoidance of illnesses. Verdant vegetables address a reasonable however excellent supplement source particularly for the helpless portion of the populace where hunger is wide spread (Ezeife, 2010).

Albeit a few vegetables can be raised nearly at lower the executive’s costs and on poor minimal soil, they have remained underutilized because of absence of consciousness of their healthy benefits, and somewhat because of the planning strategies, for fascinating vegetables. Vegetables are considered as significant supporters of a sound eating routine and their admission is of central need to decrease the danger of explicit infections like malignant growths, cardiovascular illnesses, neural cylinder deformities, and waterfalls. They are the chief wellspring of carotenoids as a result of their significant role in diet as sources to Pro-vitamin A carotenoids (Haskell, 2013). Bioactive constituents from vegetables, like carotenoids, folic corrosive and dietary fiber will in general assume significant parts in the anticipation of these infections. Lacking food and supplement consumption, helpless sustenance schooling, unseemly homegrown handling procedures and food planning strategies are among the significant reasons for ailing health (Ifesan et al., 2014). The ideal wellbeing and sustenance of people reliant upon an ordinary and adjusted inventory of food and water, and when diets are problematic, a person's ability for work and accomplishments is enormously diminished; roughly 30 % of ladies devour not exactly their day by day prerequisites of energy and something like 40 % of ladies’ overall experience the ill effects of iron-inadequacy weakness, (FAO, 2012).

The micro-nutrient content of green verdant vegetables might possibly resolve the issue of micronutrient inadequacy among the rustic inhabitants in Nigeria. Comparable to wellbeing, sensible measure of vegetable admission has been accounted for to decrease the danger of degenerative illnesses like malignancy, diabetes mellitus and cardiovascular infections (Ukom and Obi, 2018). By and by, there has been an expanding mindfulness on the requirement for remembering more vegetables for our eating routine to keep a solid body. To this date, a few specialists have disentangled various reasons why the pace of delivering vegetables and organic product should increment tremendously. There is a need to remember more leafy foods for our eating regimen and the advantages of eating more products of the soil consistently are various. Carotenoids are plant shades labile for radiant red, yellow and orange tones in many products of the soil. Carotenoids and their subsidiaries are flexible isoprenoids and they assume an imperative part in plants and creatures (Ramesh et al., 2015). Individuals who eat food sources containing carotenoids get defensive medical advantages also. Carotenoids are lipophilic regular plant colors, which are processed by plants, green growth, and photosynthetic microscopic organisms (Ramesh et al., 2015). They are classes of natural mixtures made out of at least two units of hydrocarbons, with every unit comprising of five carbon particles masterminded in a particular example (regular isoprenoid shades). They are labile for the yellow, orange, and red tones in different leafy foods (Namitha and Negi, 2010). Carotenoids serve two key roles in plants and green growth: they retain light energy for use in photosynthesis, and they shield chlorophyll from photograph harm. The main part of carotenoids in our eating regimen is the cell reinforcement and supportive of pro-vitamin A action, and furthermore the shading that they grant to our food, (Skibsted, 2012). The most widely recognized ones in the western eating regimen, and the most contemplated, are alpha-carotene, beta-carotene, beta-cryptoxanthin, lutein, lycopene and zeaxanthin.

There are two expansive characterizations of carotenoids: carotenes and xanthophylls. Carotenoids can be characterized dependent on useful gatherings; xanthophylls, containing oxygen as utilitarian gathering, including lutein and zeaxanthin, and carotenes, which contain just parent hydrocarbon chain with no practical gathering, for example, α-carotene, β-carotene and lycopene, (Ramesh et al., 2015). Expansion of polar gatherings (epoxy, hydroxyl and keto) changes the extremity of carotenoids and influences organic capacities (Britton, 2008). Carotenoids assist plants with engrossing energy for use in photosynthesis. They additionally have a significant cancer prevention agent capacity of deactivating free revolutionaries’ single oxygen iotas that can harm cells by responding with different atoms (Ramesh et al., 2015). A few carotenoids are forerunners of pro-vitamin A, which is vital for vision and ordinary development and improvement. Carotenoids likewise have calming and resistant framework benefits. Epidemiological examinations showed that the utilization of diets wealthy in carotenoids is related with a lower frequency of malignant growth, cardiovascular sicknesses, age related macular degeneration and waterfall development (Sharoni et al., 2012 Meyers et al., 2014). Inadequacy of carotenoids brings about clinical indications of conjunctiva and corneal abnormalities including, xerophthalmia, night visual deficiency, keratomalacia, corneal ulceration, scarring, and resultant irreversible visual impairment (Sommer, 2008). Lycopene is the amazing cell reinforcement carotenoid however it needs Pro-vitamin A movement yet its strong cell reinforcement action is liable for the insurance of cell framework from an assortment of receptive oxygen and responsive nitrogen species and furthermore helps in forestalling cardiovascular sicknesses in human (Muller et al., 2016). Because of carotenoids adaptable use in food sources, beauty care products and drug businesses, it makes them possible for improvement and control (Ramesh et al., 2015).

Underutilized vegetables are those vegetables that have under-took advantage of possibilities for adding to food security, wholesome, therapeutic and pay age (Anil et al., 2018). They may not be generally known outside of a particular region or locale, and there is discernment that they are filled for the most part in rustic regions (Anil et al., 2018). In certain spots utilization of these plants isn't socially adequate by certain networks since they are viewed as nourishment for poor people. They have likely advantages however need public or worldwide acknowledgment and appreciation (Anil et al., 2018). They can possibly add to neediness end through business openings and pay age and furthermore through further developed effectiveness and productivity of ranch family work use in both country and metropolitan conditions (Anil et al., 2018). With the utilization of underutilized vegetable yields, there is an approach to decrease the danger of over-dependence on extremely set number of significant harvests. They can add to supportable occupations through family food security as they can broaden the food edibility choices (Anil et al., 2018). They add supplements to the eating regimen and are here and there comfort food varieties for low pay metropolitan individuals (Anil et al., 2018). For instance, numerous underutilized vegetables contain more vitamin C and supportive of Pro-vitamin A than generally accessible business species and assortments. Concentrating on underutilized vegetables is a powerful method to assist with keeping a different and solid eating routine and to battle micronutrient lacks, the alleged 'covered up hunger', and other dietary inadequacies especially among the country poor and the weaker gatherings of people in non-industrial nations (Anil et al., 2018).

Age-related macular degeneration is a significant reason for irreversible visual impairment among the older in the Western world and aﬀects the macula lutea (yellow spot) of the retina, the space of maximal visual action (Stahl and Sies, 2005). Vitamin A is a fundamental micronutrient for the typical working of the visual and resistant frameworks, development and advancement, support of epithelial cell uprightness, and for multiplication. Vitamin A lack is the main source of preventable visual impairment in kids and builds the danger of sickness and passing from serious diseases (Ceballos et al., 2017). In pregnant ladies, Vitamin A lack causes night visual impairment and may expand the danger of maternal mortality. It is a general medical condition in the greater part, all things considered, particularly in Africa and South-East Asia. An expected 250,000 to 500,000 Vitamin A inadequate kids become visually impaired each year, a big part of them passing on inside a year of losing their sight (Ceballos et al., 2017).

1.2 STATEMENT OF PROBLEM

In spite of the abundance of green leafy vegetables in our environment and their utilization in the preparation of customary soups and dishes, data on Pterocarpus santalinoides, carotenoid is lacking. The need to expand the use of these vegetables cannot be over stressed. Micronutrient deficiency is a common place among the populace. In non-industrial nations, similar to Nigeria, vitamin A (retinol) deficiency is predominant amongst preschool children, pregnant women, lactating mothers and even all adults. This can cause visual deficiency, poor development, and death (World Health Organization, 2002, Gurmu et al., 2014). Pro-vitamin A, iron, zinc etc are micronutrients that contribute immensely to human wellbeing and deficiencies lead to paleness and low serum retinol (Underwood, 1998; Ortiz, 2011) and furthermore iodine helps in memory improvement. In any case, food diversity with vegetables high in micronutrients and carotenoids can be a panacea to wellbeing challenges presented by micronutrient inadequacy among the populace (Anil et al., 2018). Some underutilized vegetables like Pterocarpus santalinoides (Nturukpa leaves) are accepted to be rich sources of micronutrients: iron, zinc, B₆, B₉, vitamin C, Pro-vitamin A, carotenoid, even iodine (Underwood, 1998). Pro-vitamin A, close by iron and iodine, is among the main micronutrients whose insufficiency involves general wellbeing concern (Underwood, 1998).

A greater part of people in the underdeveloped nations can't fulfill their wholesome necessities for development and advancement. This prompts lack of healthy sustenance, which is one of the significant reasons for death, especially in babies and little youngsters. Hunger can show as protein-energy, lack of healthy sustenance and micronutrient inadequacy. Micronutrients are engaged with digestion of energy supplements and their insufficiency might accelerate. It is just as their particular insufficiency sicknesses (Onoja, 2014). Paleness establishes a genuine medical condition in numerous tropical nations including Nigeria in view of the pervasiveness of jungle fever and other parasitic diseases which conceivably prompts lessening of hemoglobin (Toma et al., 2015). Pterocarpus santalinoides (Nturukpa leaves) are wealthy in iron which assumes a part in the fix of pallor. Handling techniques, notwithstanding, can lessen or improve the micro-vitamin content of food sources. In addition, supplement accessibility in food varieties is better considered at the prepared conditions before utilization. It is subsequently critical to think about the impacts of handling on the phytochemical pieces, supplement arrangements, carotenoid profile of underutilized vegetables in maximum usage, for example, Pterocarpus santalinoides (Nturukpa leaves).

1.3 OBJECTIVE OF THE STUDY

The main objective of this study was to determine the effects of processing methods on the nutrient composition, phytochemicals and carotenoid profile of two cultivars of Pterocarpus santalinoides (Nturukpa leaves).

1.4 SPECIFIC OBJECTIVES OF THE STUDY

v The specific objectives of this study were: To determine the proximate, vitamin and mineral composition of two cultivars of Pterocarpus santalinoides leaves.

v To evaluate some of the phytochemicals present in the two cultivars of Pterocarpus santalinoides leaves.

v To determine the carotenoid profile of two cultivars of Pterocarpus santalinoides leaves.

v To evaluate the effects of processing on the nutrient and phytochemical composition of the two cultivars of Pterocarpus santalinoides leaves.

v To evaluate the effects of processing on the carotenoid profile of the two cultivars of Pterocarpus santalinoides leaves.

1.5 JUSTIFICATION

Cataract as a deficiency disease of Pro-vitamin A, cancer cells and malnutrition has affected many ageing and aged people. There is an urgent need to diversify means of combating eye defects which is caused by cataract since many people cannot have access to surgery and many does not want to attempt surgery because of its risk factors (most especially the rural dwellers). Also, there is an urgent need to know the carotenoid content of the leaves under study and to ascertain if they are good sources of β-carotene, hence could reduce the risk of cancer. Numerous cases of anaemia could be reduced by increasing blood level of individuals through optimal utilization of our locally available underutilized vegetables- Pterocarpus santalinoides. Some underutilized vegetables have been reported to be very good in blood building (Toma et al., 2015). It has been established that green vegetables contribute significantly to the daily dietary requirements of calcium (Ca) and iron (Fe) among children within the ages 2 to 5 years and even older adults (Ogbuji et al., 2016). Heat treatment can lead to a change in the chemical structures of vegetables, leading to the breakdown of cells and the degradation of some phenolic compounds from biological structures, the release of phenolics from the food matrix, and the conversion of insoluble phenolics to more soluble forms. In addition, the phenolic compounds are soluble in water; thus, water-based cooking techniques often lead to loss of phenolics by leaking (Kamalaja et al., 2018). It is therefore envisaged that results from this study will enlighten the public mostly, the rural and vulnerable population of the nation, on the processing methods with better carotenoid profile and nutients availability in Pterocarpus santalinoides (Nturukpa leaves) which are commonly consumed in South East Nigeria.

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