ISOLATION, CHARACTERIZATION AND ANTIMALARIAL ACTIVITY OF BIOACTIVE COMPONENTS FROM THE LEAVES OF ALCHORNEA CORDIFOLIA (SCHUMACH. & THONN.) MULL. ARG

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ABSTRACT

Alchornea cordifolia is known for its phytomedicinal properties including its antimalarial potentials. This research was aimed at isolation and characterization of bioactive components from the leaves of Alchornea cordifolia as well as investigating by in vitro, the antimalarial activities of its crude methanol extract and fractions of petroleum ether, dichloromethane, ethyl acetate and methanol, on human whole blood medium, infected with Plasmodium falciparum. Phytochemical analysis, antimalarial activity and spectral characterization were done using standard methods. Through phytochemical screening we discovered the presence of tannins, flavonoids, alkaloids, phenols, saponins, and cyanogenic glycosides. The result of the spectral analysis revealed two compounds shown to possess identical spectral properties but with a distinct addition of two olefinic protons on the NMR at C-22 and C-23 in the case of one compound. The two compounds possess a steroidal skeleton with molecular masses of 412 and 414 and molecular formulas of C29H48O and C29H50O respectively. The two compounds interpreted from the spectral results are Stigmasterol and β-sitosterol respectively. Based on the IR we also proposed a third possible structure as a stigmasterol analog. The third structure still of molecular formula C29H48O has an aldehydic functional group, CHO replacing the CH3 on C-18 but with absence of OH on C-3. On antimalarial activity, the crude methanol extract and ethyl acetate fraction showed a good dose-dependent antimalarial activity with mean IC50 values of Parasitaemia (P) = 12.2 and P = 12.94 respectively, while those of standard drugs, chloroquine and ACT, used as positive control were 13.38 and 9.2 respectively. These mean IC50 values indicate that crude methanol extract and ethyl acetate fraction gave a better antimalarial activity than chloroquine but were not as good as ACT. Using one way ANOVA for statistical analysis we confirmed our significant results. Hence the leaves of Alchornea cordifolia possess promising bioactive components that showed significant antimalarial activity against Plasmodium falciparum and may give a better activity when they work in synergy. Thus, it will be potentially effective in the fight against malaria.

TABLE OF CONTENTS

Title Page i Declaration ii

Certification iii

Dedication iv

Acknowledgements v

Table of Contents vi

List of Tables viii

List of Figures ix

List of Plates xi

List of Charts xii

List of Abbreviations xiii

Abstract xiv

CHAPTER 1: INTRODUCTION 1

1.1 Background of the Study 1

1.2 Statement of the Problem 2

1.3 Aim of the Study 3

1.4 Objectives of the Study 3

1.5 Justification of the Study 3

1.6 Scope of the Study 4

CHAPTER 2: LITERATURE REVIEW 5

2.1 Botanical Characteristics of Alchornea cordifolia 5

2.2 Phytomedicinal Properties 7

2.3 Phytochemical Constituents 7

2.4 Phytochemicals 8

2.5 Plasmodium Species and Life Cycle 20

2.6 Antimalarials 21

2.6.1 Natural product antimalarials 22

2.6.2 Synthetic antimalarials 27

2.6.3 Coartem (artemether/lumefantrine) 29

2.7 Thin Layer Chromatography (TLC) 30

2.8 Column Chromatography 31

2.9 Spectroscopic Techniques 34

2.10 In Vitro Antimalarial Activity 44

CHAPTER 3: MATERIALS AND METHODS 49

3.1 Materials 49

3.2 General Experimental Procedure 50

3.2.1 Plant material 50

3.2.2 Extraction of plant material 50

3.2.3 Isolation of constituents 51

3.2.4 Qualitative phytochemical analysis 54

3.2.5 Quantitative phytochemical determination 56

3.2.6 Structure elucidation 60

3.2.7 In vitro antimalarial activity 62

CHAPTER 4: RESULTS AND DISCUSSION 67

4.1 Column Chromatography 67

4.2 Thin Layer Chromatography (TLC) 69

4.3 Phytochemical Analysis 70

4.4 Spectral Analysis 73

4.5 In Vitro Antimalarial Activity 72

CHAPTER 5: CONCLUSION AND RECOMMENDATIONS 112

5.1 Conclusion 112

5.2 Recommendations 112

References 114

LIST OF TABLES

2.5 Duration of Phases of Plasmodium Species 21

2.6.1 Examples of Antimalarial Herbal Isolates 22

2.10.7 Summary of Assay Methods 48

4.1.1 Column Chromatography (First Phase) 67

4.1.2 Column Chromatography (Second Phase) 67

4.2.1 TLC of Pure Components from Column Chromatography

(First Phase) 69

4.2.2 TLC of Pure Components from Column Chromatography

(Second Phase) 69

4.3.1 Phytochemical Analysis 70

4.3.2 Cyanogenic Glycosides 71

4.4.1 DEPT, ¹³C NMR and ¹H NMR Chemical shifts of Compound 1

(stigmasterol) recorded in CDCl₃ 97

4.4.2 ¹³C NMR and ¹H NMR Chemical Shift Values of Compound 2

(β-sitosterol) recorded in CDCl₃87

4.5.1 In vitro Antimalarial Activity of BC 95

4.5.2 In vitro Antimalarial Activity of CME 96

4.5.3 In vitro Antimalarial Activity of PEF 96

4.5.4 In vitro Antimalarial Activity of DMF 97

4.5.5 In vitro Antimalarial Activity of EAF 97

4.5.6 In vitro Antimalarial Activity of MF 98

4.5.7 In vitro Antimalarial Activity of CQ 98

4.5.8 In vitro Antimalarial Activity of ACT 99

4.11 Statistical Analysis using One Way Anova including Turkey HSD 108

LIST OF FIGURES

2.4.1 Phenolic Compounds Isolated from Alchornea Species 10

2.4.2 Flavonoids Isolated from Alchornea Species 14

2.4.3 Alkaloids Isolated from Alchornea Species 16

2.4.4 Steroids Isolated from Alchornea Species 19

2.5 Plasmodium Species and Life Cycle 20

2.6.2.1 Chloroquine 27

2.6.2.2 Quinine derivatives 27

2.6.2.3 Lumefantrine 28

2.6.2.4 Artemisinin and its derivatives 28

2.9.2 IR absorption range and fingerprint region 37

2.9.3.1 Proton Chemical shifts and Chemical Environments 40

2.9.3.2: Carbon-13 Chemical Shifts and Chemical Environments 41

2.9.4.1: DEPT-Distortionless Enhancement by Polarisation Transfer 41

2.9.4.2: DEPT-Distortionless Enhancement by Polarisation Transfer 42

2.9.5: 2D COSY 43

4.4.1 FT-IR Spectrum of ND-2 from EA21 73

4.4.2 ¹H-NMR Spectrum of ND-2 from EA21 75

4.4.3 COSY Spectrum of ND-2 from EA21 76

4.4.4 ¹³CNMR Spectrum of ND-2 from EA21 77

4.4.5 ¹³CNMR Spectrum of ND-2 from EA21 78

4.4.6 DEPT Spectrum of ND-2 from EA21 79

4.4.7 DEPT Spectrum of ND-2 from EA21 80

4.4.8 ¹H-NMR Spectrum of ND-2 from EAF3 84

4.4.9 COSY Spectrum of ND-1 from EAF3 85

4.4.10: DEPT Spectrum of ND-1 from EAF3 86

4.4.11: MS Spectrum of ND-1 from EAF3 88

4.4.12: Stigmasterol (Compound 1) 90

4.4.13: β-Sitosterol (Compound 2) 90

4.4.14: The Third Proposed Structure 91

4.5.1 In vitro Antimalarial Plot of BC 100

4.5.2 In vitro Antimalarial Plot of CME 101

4.5.3 In vitro Antimalarial Plot of PEF 102

4.5.4 In vitro Antimalarial Plot of DMF 103

4.5.5 In vitro antimalarial Plot of EAF 104

4.5.6 In vitro Antimalarial Plot of MF 105

4.5.7 In vitro Antimalarial Plot of CQ 106

4.5.8 In vitro Antimalarial Plot of ACT 107

LIST OF PLATES

2.1 Leaves of Alchornea cordifolia 6

LIST OF CHARTS

3.1 Fractionation of Crude Methanol Extract from the Leaves of

Alchornea cordifolia 66

LIST OF ABBREVIATIONS

A.cordifolia – Alchornea cordifolia

BC – Blood Control wells

CME – Crude Methanol extract

DM – Dichloromethane

DMF – Dichloromethane fraction

EA – Ethyl acetate

EAF – Ethyl acetate fraction

M – Methanol

ME – Methanol extract

P- Parasitaemia

PE – Petroleum ether

PEF – Petroleum ether fraction

PW- Precautionary wells

SW – Supplementary wells

CHAPTER 1

INTRODUCTION

The last decade has witnessed an upsurge in the use of herbs as a source of medication (WHO, 2004). Some herbs like Artemisia annua have also become the basis for some pharmaceutical medications. The “phytochemical world” has of recent attracted many researchers due to the healthy phytochemicals derived from plants (WHO, 2004; 2006). Prominent among herbs are those for the treatment of malaria because malaria poses a great threat to more than half of the world’s population (WHO, 2015).

Of the prominent antimalarial herbs is Alchornea cordifolia (A. cordifolia). It is mostly used for medicinal purposes and widely distributed in the east, south, west and central Africa (www.prota4u.org). Among its phytochemical benefits is its traditional use as an antimalarial. A. cordifolia is thus the focus of this research because of its traditional effectiveness.

1.1 BACKGROUND OF THE STUDY

The term malaria originates from Medieval Italian: “mala aria” meaning “bad air” (Reiter, 1999). The disease is endemic in the tropical and sub-tropical zones around the equator (Caraballo, 2014) due to high temperatures and high humidity, heavy rainfall as well as stagnant water which is a breeding ground for mosquitoes. These regions are more of sub-Saharan Africa, Asia and Latin America (WHO Malaria Fact Sheet, 2014). The worldwide malaria report states that in 2018, there were about 228 million cases of malaria, with 85% of these cases in sub-Saharan Africa and India. Of all the malaria cases worldwide, six countries were accountable for more than half. To our dismay, our country Nigeria ranks topmost on this statistics, being accountable for about 25%. This is alarming! Mortality rate is still on the high side globally, reaching up to 405,000. (WHO, 2019). This rapid spread of malaria and high mortality rate call for prompt actions which might include the use of more antimalarial phytomedicines.

1.2 STATEMENT OF THE PROBLEM

Malaria is a deadly disease caused by parasites (Plasmodium falciparum, Plasmodium vivax, Plasmodium ovale, Plasmodium malariae, Plasmodium knowlesi), transmitted to humans when bitten by infected female Anopheles mosquitoes. Plasmodium falciparum and Plasmodium vivax pose the greatest threat. Plasmodium Knowlesi was recognized by World Health Organization, WHO in 2008 and rarely causes diseases in humans (WHO, 2008; WHO, 2017).

The most prominent transmission medium is through bites from infected female Anopheles mosquitoes that had a blood meal from an individual infected with the parasitaemia. Other media of transmission include blood transfusion, organ transplant, unsterilized needles, and from a pregnant mother to her fetus. Symptoms of malaria which usually begin within fifteen days include fever, vomiting, headaches and tiredness (Caraballo, 2014). Severe symptoms result in jaundice, coma, seizures, cerebral malaria or even death (Bartoloni and Zammarchi, 2012). In pregnant women, malaria results in stillbirths, decrease in birth weight, abortion or infant mortality. Disastrous consequences indeed!

Methods used to prevent malaria include medications, vector control and prevention of bites. Treatment of malaria with antimalarial medications is highly endorsed. From a public health perspective, one of the goals of treatment of malaria is to prevent offshoot and recurrence of resistance to antimalarial medicines (WHO, 2018).

1.3 AIM OF THE STUDY

To investigate the potentiality of A. cordifolia as an antimalarial agent.

1.4 OBJECTIVES OF THE STUDY

Isolation and characterization of the bioactive components from the leaves of A. cordifolia as well as investigating by in vitro its antimalarial potentials.

1.5 JUSTIFICATION OF THE STUDY

Malaria has posed a great threat to a greater number of the world’s population. Thus, there is a prompt need for more antimalarials to curb drug resistance and reduce mortality rate. If A. cordifolia is investigated and adopted as an antimalarial, it may result in great benefits to malaria endemic zones and humanity in general with the following possible benefits:

i. Possibility of being proposed and tested as an alternative to existing antimalarials;

ii. Ability to serve as a good source of phytochemicals for further production of conventional antimalarials;

iii. The phytochemical marker from A. cordifolia can provide the basis for parallel drug development of synthetic antimalarials;

iv. The fact that it is a widely distributed herb (www.prota4u.org), implies it will be easily accessible by patients in remote areas; hence it may serve as a complement to existing antimalarials.

1.6 SCOPE OF THE STUDY

Based on its traditional use as a cure for malaria, this research work aims at isolating, purifying and investigating the antimalarial potentials of the bioactive components from the leaves of A. cordifolia.

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