ASSESSMENT OF THE CARDIOPROTECTIVE POTENTIAL OF THE ETHANOL LEAF EXTRACT OF PTEROCARPUS SANTALINOIDES IN WISTAR RATS

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ABSTRACT

Cardiotoxicity has become a major challenge for cancer patients undergoing chemotherapy. Examples of potentially cardiotoxic anticancer agents are 5-fluorouracil and anthracyclines. The leaves of Pterocarpus santalinoides have been shown to possess among other pharmacological properties, the ability to lower serum levels of low density lipoprotein cholesterol (LDL-C) which suggests a cardio protective potential. This study was aimed at experimenting the cardioprotective potential of the ethanol leaf extract against cardiotoxicity side effect of 5-fluorouracil in wistar rats. The study was done in two phases. 36 albino rats were employed for the first phase of the study, they were separated into 6 groups (groups 1, 2, 3, 4, 5 and 6) of 6 animals which received (distilled water, distilled water, 25 mg/kg Aspirin, 34.54 mg/kg crude extract, 69.28 mg/kg crude extract and 103.92 mg/kg crude extract for groups 1, 2, 3, 4, 5 and 6 respectively) orally for a period of 14 days. On the 15th day, groups 2, 3, 4, 5, and 6 were given 5-fluorouracil (150 mg/kg) via intra-peritoneal route to induce cardiotoxicity. After a period of 24 hours, the animals were sacrificed, the sera were analyzed for troponin T, CK-MB, Lipid profile, the whole blood samples were subjected to haematology while the hearts were subjected to histopathological scrutiny, the result obtained revealed significant (p<0.05) increase in HDL-C and decrease in LDL-C, Troponin T and CK-MB across groups compared to positive control which indicates cardioprotective potential, hence the second phase was conducted. In the second phase, the crude extract was fractionated into n-butanol, ethyl acetate and chloroform fractions, 36 albino wistar rats were also used for the study. They were also separated into 6 groups of 6 animals each. The animals were equally given treatments (distilled water, distilled water, 25 mg/kg Aspirin, 69.28 mg/kg n-butanol fraction, 69.28 mg/kg ethyl acetate fraction and 69.28 mg/kg chloroform fraction for groups 1, 2, 3, 4, 5 and 6 respectively) orally for 14 days. On the 15th day, groups 2, 3, 4, 5 and 6 were given 5-FU (150 mg/kg) via intraperitoneal route to induce cardiotoxicity. The animals were sacrificed after 24 hours, and the sera analyzed for troponin T level, CK-MB activity; lipid profile; urea, creatinine and electrolytes concentrations; ALP, AST and ALT activity; malondialdehyde concentration, catalase, glutathione peroxidase, superoxide dismutase activity; the whole blood samples were haematologically analyzed and the heart, kidney and liver tissues were histologically studied. Result revealed significant decrease (p<0.05) in TnT, CK-MB, LDL-C, TG, WBC, platelets, ALP, AST, ALT, urea, creatinine, Na+, K+, Cl-, HCO-3 and significant (p<0.05) increase in HDL-C, RBC, Ca2+, catalase, SOD and GSPx activity across groups as compared to the positive control. Histopathological results revealed that the low and medium dose of crude extract and chloroform fraction yielded more effective protection from cardiotoxicity more than the other doses and fractions. The crude ethanol extract of P. santalinoides and its fractions conferred on the albino rats appreciable protection against 5-FU induced cardiotoxicity with the medium dose and chloroform fraction producing the overall highest cardioprotective effects.

TABLE OF CONTENTS

Title Page i

Declaration ii

Certification iii

Dedication iv

Acknowledgements v

Table of Contents vi

List of Tables xii

List of Figures xiii

List of Plates xii

List of Appendixes xv

List of Abbreviations xvii

Abstract xix

CHAPTER 1: INTRODUCTION

1.1 Background of the Study 1

1.2 Pterocarpus santalinoides (PS) 7

1.3 Scope of the Study 10

1.4 Statement of Problem 11

1.5 Justification of the Study 12

1.6 Relevance of the Study 13

1.7 Aim of the Study 14

1.8 Objectives of the Study 14

CHAPTER 2: REVIEW OF RELATED LITERATURE

2.1 Phytochemical and Proximate Composition of Pterocarpus santalinoides 15

2.1.1 Phytochemistry of Pterocarpus santalinoides 15

2.1.2 Proximate composition of Pterocarpus santalinoides 16

2.2 Pharmacological Activities of Pterocarpus santalinoides 17

2.2.1 Analgesic activity 17

2.2.2 Insecticidal activity 17

2.2.3 Antitrypanosomal activity 19

2.2.4 Haematological effects 19

2.2.5 Hypolipidemic activity 19

2.2,6 Anti-cancer activity 20

2.2.7 Antimicrobial activity 21

2.2.8 Anti-diarrhoeal and antispasmodic activity 22

2.3 Cardioprotective Effect of Aspirin 24

2.4 Anti-Cancer agents and their Cardiotoxicity Potential 25

2.4.1 5-Fluorouracil and other antimetabolites 25

2.4.2 Trastuzumab (Herceptin) 27

2.4.3 Anthracyclines 28

2.4.4 Taxanes 30

2.4.5 Interleukin-2 (IL-2) therapy 31

2.4.6 Tyrosine kinase inhibitors (TKIs) 31

2.4.7 Checkpoint inhibitors immune therapy 32

2.4.8 Angiogenesis inhibitors 33

2.4.9 Radiation therapy 34

2.5 Biomarkers of Cardiotoxicity 35

2.5.1 Cardiac function status 35

2.5.1.1 Troponin 35

2.5.1.2 Creatine kinase (EC 2.7.3.2) 36

2.5.1.3 Lactate dehydrogenase (EC 1.1.1.27) 37

2.5.1.4 Natriuretic peptide 38

2.5.2 Peripheral blood mononuclear cell gene expression profile 40

2.5.3 Lipid profile (cardiovascular risk factor assessment) 41

2.5.3.1 Cholesterol 41

2.5.3.2 Triglycerides 43

2.5.4 Liver function status 43

2.5.4.1 Alkaline Phosphatase (ALP) (EC 3.1.3.1) 44

2.5.4.2 Aminotransferases: ALT (EC 2.6.1.2) and AST (EC 2.6.1.1) 45

2.5.5 Oxidative stress status 47

2.5.5.1 Malondialdehyde (MDA) 47

2.5.5.2 Catalase (EC 1.11.1.6) 48

2.5.5.3 Superoxide dismutase (EC 1.15.1.1) 50

2.5.5.4 Glutathione peroxidase (EC.1.11.1.9) 51

2.5.6 Haematological indices 52

2.5.6.1 Red blood cell (erythrocytes) count and haemoglobin (Hb) 54

2.5.6.2 White blood cell (WBC) count 56

2.5.5.3 Platelet count 56

2.5.7 Kidney function status 57

2.5.7.1 Serum potassium 57

2.5.7.2 Serum sodium 59

2.5.7.3 Serum bicarbonate 60

2.5.7.3 Serum creatinine 61

2.5.7.4 Serum urea 62

CHAPTER 3: MATERIALS AND METHODS

3.1 Materials 64

3.1.1 Chemicals and reagents 64

3.1.2 Equipment 64

3.1.3 Research hypothesis 65

3.2 Methods 65

3.2.1 Plant leaf collection, identification and extraction of

the crude ethanol extract 65

3.2.2 Extract fractionation by partitioning 66

3.2.3 Determination of median lethal dose (LD₅₀) for the crude ethanol

extract 66

3.2.4 Phytochemical screening 68

3.2.4.1 Test for alkaloids 68

3.2.4.2 Test for saponins 68

3.2.4.3 Test for tannins 68

3.2.4.4 Test for flavonoids 69

3.2.4.5 Test for cardiac glycosides 69

3.2.4.6 Test for anthraquinones 69

3.2.5 Experimental design 70

3.2.6 Experimental animals treatment 71

3.2.7 Animal sacrifice and preparation of sera for phase one studies 72

3.2.8 Animal sacrifice and preparation of sera for phase two studies 73

3.3 Biochemical Analysis 75

3.3.1 Estimation of serum troponin-T concentration 75

3.3.2 Estimation of CK-MB concentration 76

3.3.3 Estimation of alkaline phosphatase activity 78

3.3.4 Estimation of serum superoxide dismutase activity 79

3.3.5 Estimation of serum glutathione peroxidase activity 80

3.3.6 Estimation of serum catalase activity 82

3.3.7 Estimation of serum malondialdehyde (MDA) level 83

3.3.8 Estimation of total serum cholesterol 84

3.3.9 Estimation of serum high density lipoprotein cholesterol 85

3.3.10 Estimation of serum level of total triglyceride 86

3.3.11 Estimation of haematological indices 88

3.3.12 Estimation of serum electrolytes level 89

3.3.13 Determination of aspartate amino transferase (AST) activity in serum 90

3.3.14 Estimation of alanine aminotransferase (ALT/SGPT) activity 91

3.3.15 Estimation of urea (BUN) 92

3.3.16 Estimation of serum creatinine concentration 92

3.3.17 Histological procedures 94

3.3.18 Statistical analysis 94

CHAPTER 4: RESULTS AND DISCUSSION

4.1 Results 96

4.1.1 Phytochemical screening 96

4.1.2 Phase one results 98

4.1.2.1 Effect of CELEPS on serum troponin-T concentration and

CK-MB activity in albino rats 98

4.1.2.2 Effect of CELEPS on serum lipid profile in albino rats 99

4.1.2.3 Effect of CELEPS on haematological parameters in albino

rats 102

4.1.2.4 Effect of CELEPS on the histopathology of the heart tissues 104

4.1.3 Phase two results 112

4.1.3.1 The effect of FELEPS on cardiovascular indices in albino rats 112

4.1.3.1.1 The effect of FELEPS on serum troponin T concentration in

albino rats 112

4.1.3.1.2 The effect of FELEPS on serum CK-MB activity in albino

rats 114

4.1.3.2 The effect of FELEPS on serum lipid profile in albino rats 116

4.1.3.3 The effect of FELEPS on liver function status in albino rats 120

4.1.3.3.1 The effect of FELEPS on serum ALP, AST and ALT activity 120

4.1.3.4 The effect of FELEPS on the oxidative stress status in albino

rats 122

4.1.3.4.1 The effect of FELEPS on the serum MDA concentration in

albino rats 122

4.1.3.4.2 The effect of FELEPS on serum levels of oxidative enzymes;

Catalase, Superoxide Dismutase and Glutathione Peroxidase in

Albino Rats 124

4.1.3.5 The effect of FELEPS on the haematological Indices in albino

Rats 125

4.1.3.6 The effect of FELEPS on kidney function status in albino rats 132

4.1.3.6.1 The effect of FELEPS on the serum electrolytes concentration in albino rats 132

4.1.3.6.2 The effect of FELEPS on the serum urea and creatinine

concentration in albino rats 135

4.1.3.7 Histopathological results 137

4.2 Discussion 155

CHAPTER 5: SUMMARY, CONCLUSION AND RECOMMENDATIONS

5.1 Summary 180

5.2 Conclusion 182

5.3 Recommendation 183

References 184

Appendix 220

LIST OF TABLES

3.1 Dose Regimen for Phase One Studies (Treatment with Crude Ethanol

Extract) 70

3.2 Dose Regimen for Phase Two (Treatment with Fractionated Portions of the

Crude ethanol extract) 72

3.3 Sample and Blank Regimen for Determination of SOD activity 79

3.4 Reagent Blank, Standard, Controls and Samples Regimen for Estimation

of Serum Creatinine Concentration 92

4.1 Result of Phytochemical Screening 95

4.2 Effect of CELEPS on Serum of Troponin Concentration and

CK-MB Activity in Albino rats 97

4.3 Effect of CELEPS on Serum Lipid Profile in Albino Rats 99

4.4 Effect of CELEPS on Haematological Parameters in Albino Rats 101

4.5 The Effect of FELEPS on Serum Lipid Profile in Albino Rats 116

4.6 The Effect of FELEPS on Lipid Profile Assessment (cardiovascular risk index) 117

4.7 The Effect of FELEPS on Serum ALP, ALT and AST Activities in Albino Rats 119

4.8 The Effect of FELEPS on the Serum MDA Concentration in Albino Rats 121

4.9 The Effect of FELEPS on Serum Activities of Oxidative Enzymes; Catalase, Superoxide Dismutase and Glutathione Peroxidase in Albino Rats 123

4.10A The Effect of FELEPS on the Haematological Indices in Albino Rats 127

4.10B The Effect of FELEPS on the haematological Indices in albino rats continued 128

4.11 The Effect of Fractions of Ethanol Leaf Extract of P. santalinoides on the Serum Electrolytes in Albino Rats. 131

4.12: The Effect of FELEPS on the Serum Urea and Creatinine Concentration in Albino Rats in Wistar rats 133

LIST OF FIGURES

4.1 The effect of fractions of ethanol leaves extract of p. santalinoides

(FELEPS) on serum troponin levels (ng/ml) in albino rats. 111

4.2 The effect of fractions of ethanol leaf extract of P. santalinoides

(FELEPS) on serum CK-MB activity (u/l) in albino rats 113

LIST OF PLATES

1.1 Pterocarpus santalinoides 7

4.1 Photomicrograph of Heart Tissue of Normal Control Rats (Treated with Distilled Water Only) 104

4.2 Photomicrograph of Heart Tissue Treated with Distilled Water and 150 mg/kg bw 5-Fluorouracil (Positive Control) 105

4.3 Photomicrograph of Heart Tissue Treated with 25 mg/kg bw Aspirin (AS) and 150 mg/kg bw 5-Fluorouracil (Standard Control) 106

4.4 Photomicrograph of Heart Tissue Treated with Low Dose (LD) (34.64 mg/kg bw) of CELEPS and 150 mg/kg bw 5-Fluorouracil (Low Dose) 107

4.5: Photomicrograph of Heart Tissue Treated with Medium Dose (69.28 mg/kg bw) of CELEPS and 150 mg/kg bw 5-Fluorouracil 108

4.6 Photomicrograph of Heart Tissue Treated with High Dose (HD) (103.92 mg/kg bw) CELEPS and 150 mg/kg bw 5-Fluorouracil. 109

4.7 Photomicrograph of the Longitudinal Section of the Distilled Water

(Control) Heart Tissue 134

4.8 Photomicrograph of the Longitudinal Section of the Heart Tissue of the Distilled Water + 150 mg/kg bw 5-Fluorouracil Treated Rats (Positive Control) 135

4.9 Photomicrograph of the Longitudinal Section of the Heart tissue of the 25mg/kg bw aspirin + 150mg/kg bw 5-Fluorouracil Treated Rats (Standard Control) 136

4.10 Photomicrograph of the Longitudinal Section of the Heart Tissue of the N-Butanol Fraction + 150mg/kg bw 5-Fluorouracil Treated Rats (Group 4) 137

4.11 Photomicrograph of the Longitudinal Section of the Heart Tissue of the Ethyl-acetate Fraction + 150mg/kg bw 5-Fluorouracil Treated Rats (Group 5) 138

4.12 Photomicrograph of the Longitudinal Section of the Heart Tissue of the Chloroform Fraction + 150mg/kg bw 5-Fluorouracil Treated Rats (Group 6) 139

4.13 Photomicrograph of the Longitudinal Section of the Kidney Tissue of the Distilled Water Treated Rats (Normal Control) 140

4.14 Photomicrograph of the Longitudinal Section of the Kidney Tissue of the Distilled Water + 150 mg/kg bw Treated Rats (Positive Control). 141

4.15 Photomicrograph of the Longitudinal Section of the Kidney Tissue of the 25mg/kg bw Aspirin + 150mg/kg 5-Fluorouracil Treated Rats (Standard Control) 142

4.16 Photomicrograph of the Longitudinal Section of the Kidney Tissue of the n-Butanol Fraction + 150 mg/kg bw Treated Rats (Group 4) 143

4.17 Photomicrograph of the Longitudinal Section of the Kidney Tissue of the Ethyl-acetate Fraction + 150 mg/kg bw Treated Rats (Group 5) 144

4.18 Photomicrograph of the Longitudinal Section of the Kidney Tissue of the Chloroform Fraction + 150 mg/kg bw Treated Rats (group 6) 145

4.19 Photomicrograph of the Transverse Section of the Liver Tissue of the Distilled Water Treated Rats (Normal Control). 146

4.20 Photomicrograph of the Transverse Section of the Liver Tissue of the Distilled Water + 150 mg/kg bw 5-Fluorouracil Treated Rats (Positive Control) 147

4.21 Photomicrograph of the Transverse Section of the Liver Tissue of the 25mg/kg bw Aspirin + 150 mg/kg bw 5-Fluorouracil Treated Rats (Standard Control) 148

4.22 Photomicrograph of the Transverse Section of the Liver Tissue of the N-Butanol Fraction + 150 mg/kg bw 5-Fluorouracil Treated Rats (Group 4) 149

4.23 Photomicrograph of the Transverse Section of the Liver Tissue of the Ethyl-acetate Fraction + 150 mg/kg bw 5-Fluorouracil Treated Rats (Group 5) 150

4.24 Photomicrograph of the Transverse Section of the Liver Tissue of the Chloroform Fraction + 150 mg/kg bw 5-Fluorouracil Treated Rats (Group 6) 151

LIST OF APPENDIXES

I Estimation of Serum Troponin 217

II Estimation of Serum CK-MB Concentration 218

III Estimation of Serum Level of Triglyceride (TG) 220

IV Estimation of Total Serum Cholesterol 221

V Estimation of Serum Level of HDL-Cholesterol 221

VI Estimation of Haematological Indices 222

VII Estimation of Serum Malondialdehyde (MDA) Level 223

VIII Estimation of Serum SOD Activity 224

IX Estimation of Serum Glutathione Peroxidase (GSPx) Activity 224

X Estimation of Serum Catalase (CAT) Activity 225

XI Estimation of Alkaline Phosphatase (ALP) Activity 225

XII Estimation of Aspartate Amino Transferase (AST) Activity 226

XIII Estimation of Alanine Amino Transferase (ALT) Activity 226

XIV Estimation of Serum Urea Nitrogen (BUN) Concentration 227

XV Estimation of Serum Creatinine Concentration 227

XVI Preparation of Extracts Doses (mg/kg bw) 228

XVII Preparation of Aspirin 25 Mg (mg/kg bw) 228

XVIII Calculation of 5-Fluorouracil Doses (mg/kg bw) 228

LIST OF ABBREVIATIONS

5-FU 5-Fluorouracil

ACE Angiotensin Converting Enzyme

ALP Alkaline Phosphatase

ALT Alanine Transaminase

AST Aspartate Transaminase

BUN Blood Urea Nitrogen

CAD Coronary Artery Disease

CAT Catalase

CBC Complete Blood Count

CDC Center for Disease Control and Prevention

CELEPS Crude ethanol extract of Pterocarpus santalinoides

CHF Congestive Heart Failure

CKD Chronic Kidney Disease

CK-MB Creatine Kinase-MB Fraction

CVD Cardiovascular Disease

DNPH Dinitrophenyl Hydrazone

FBC Full Blood Count

FDA Food and Drug Administration

FELEPS Fractions of Ethanol Extract of Pterocarpus santalinoides

GGT Gamma-Glutamyl Transferase

GSPx/GPx Glutathione Peroxidase

H &E Hematoxylin and Eosin

Hb/HGBS Haemoglobin

HDL-C High Density Lipoprotein Cholesterol

HER2 Human Epidermal Growth Factor Receptor 2

HF Heart Failure

HIV Human Immunodeficiency Virus

LD₅₀Lethal Dosage

LDL-C Low Density Lipoprotein Cholesterol

LV Left Ventricle

LVD Left Ventricular Dysfunction

LVEF Left Ventricular Ejection Fraction

Mabs Monoclonal Antibodies

MDA Malondialdehyde

MEPS Methanol Leaf Extract of Pterocarpus santalinoides

MI Myocardial Infarction

NO Nitric Oxide

NSAID Nonsteroidal Anti-inflammatory Drug

PMBC Peripheral blood Mononuclear Cells

PS Pterocarpus santalinoides

RBC Red Blood Cell

SGOT Serum Glutamic Oxaloacetic Transaminase

SGPT Serum Glutamic Pyruvic Transaminase

SOD Superoxide Dismutase

TC Total Cholesterol

TKIs Tyrosine Kinase Inhibitors

TnI Troponin I

TnT Troponin T

UA Uric Acid

VEGF Vascular Endothelial Growth Factor

VLDL Very Low Density Lipoprotein

WBC White Blood Cell

CHAPTER 1

INTRODUCTION

1.1 BACKGROUND OF THE STUDY

In many nations of the world, cardiovascular diseases (CVD) are leading causes of deaths despite several advancements in the medical interventions. Some of the CVDs include: coronary heart disease, peripheral arterial disease, rheumatic heart disease, congenital heart disease, strokes, myocardial ischemia and myocardial infarction (heart attack) (Arnett et al., 2014). Myocardial ischemia (MI) remains a major pathological cause of death globally despite rapid advancements continously made in the treatment of coronary diseases (Murray and Lopez, 1997; Boudina et al., 2002). Most cancer therapies have been linked with risk of causing cardiotoxicity (Curgliano et al., 2010; Hahn et al., 2014). Over the years and even in recent times, the number of deaths caused by cardiovascular diseases (CVD) have been on the increase even in developed nations such as USA, UK, Germany and others. It’s a leading cause of death in the United States. According to the Centers for Disease Control and Prevention (CDC), one American dies from cardiovascular disease every 37 seconds. The most common factors that can increase the risk for cardiovascular disease include high blood pressure, high blood cholesterol, diabetes, smoking, sedentary lifestyle (physical inactivity), and obesity.

Cardiotoxicity refers to toxicity that affects the heart. It can be defined as new onset or worsening of myocardial damage or ventricular function from baseline during follow-up (Sanz and Zamorano, 2020). It can also be referred to as the damage to the myocardium induced by medication, which can precipitate pathological conditions such as heart failure (HF), hypertension and structural damage. Cardiotoxicity can also be defined as either the presence of symptoms of heart failure with greater or equal to five percent (≥5%) reduction in ejection fraction to less than fifty - five percent (<55%) or the absence of symptoms with an ejection-fraction reduction ≥10% to <55% (Csapo and Lazar, 2014). Cardiotoxicity is a known adverse effect of many conventional chemotherapeutic agents. many of the new cancer drugs also interact with cardiovascular signalling and have important side effects, particularly during times of increased cardiac stress (Suter and Ewe, 2013). Cardiac dysfunction and heart failure are among the most serious cardiovascular side effects of systemic cancer treatment (Suter and Ewe, 2013). When cancer patients undergo chemotherapy or radiotherapy they eventually suffer from cardiotoxicity as a result of the treatment, their quality of life and overall survival is severely affected, but suspending the treatment of cancer for fear of the cardiotoxicity risk is actually not the best option, therefore early detection of such condition by pharmacists and physicians during chemotherapy is very crucial. Most already established and newer anticancer drugs have this cardiotoxicity side effect. In other not to deny a patient the the ability to benefit from cancer treatment, a new field of medical specialty known as Cardio-oncology has been established in other to manage the cardiotoxicity side effect while the patient continues with the cancer treatment (Suter and Ewe, 2013). Cardio-oncology has emerged as a sub-specialty to meet the challenges posed by a complex interaction between cancer and the cardiovascular system and the cardiotoxicity of conventional and newly developed cancer therapies (Fiuza et al., 2016; Diwakar et al., 2017).

Cardiotoxic drugs are divided into four categories:

1) Drugs that cause direct cytotoxicity on the heart resulting to cardiac dysfunction: examples of such drugs include the alkylating agents, anthracyclines, tyrosine kinase inhibitors (TKIs), interferon alfa and monoclonal antibodies (Mabs)

2) Drugs that can cause cardiac ischemia: examples include antitumor antibiotics, fluorouracil (5-FU), topoisomerase inhibitors.

3) Drugs that can precipitate cardiac arrhythmias: e.g. anthracyclines, etc.

4) Drugs that can cause pericarditis: e.g. bleomycin, cyclophosphamide, cytarabine (Csapo and Lazar, 2014)

According to the system proposed by Ewer et al. (2013), cardiotoxicity of cancer drugs can be categorized based on their potential to cause irreversible damage (type 1) or reversible damage (type 2). Type 1 damage is usually caused by a cumulative dose; type 2 damage is not related to a cumulative dose. Examples of anti-cancer agents that can cause irreversible toxicity include anthracyclines (daunorubicin, idarubicin, doxorubicin, epirubicin); taxanes (docetaxel, paclitaxel, cabazitaxel); topoisomerase inhibitors (etoposide, tretinoin, vinca alkaloids); alkylating agents (busulfan, carboplatin, mitomycin, carmustine, chlormethine, cisplatin, cyclophosphamide); and antimetabolites (cladribine, cytarabine, 5-FU) (Csapo and Lazar, 2014; Romond et al., 2005).

The most common chemotherapy agents associated with irreversible damage to the heart are the anthracyclines. Anthracyclines, especially doxorubicin, are used to treat several types of cancer, including breast, gynecologic, sarcoma, and lymphoma. Csapo and Lazar (2014) reported that the mechanisms by which anthracyclines cause cardiotoxicity is by inducing necrosis and apoptosis of cardiac myocytes and subsequent myocardial fibrosis. Doxorubicin-induced cardiotoxicity involves several processes, such as the formation of iron-dependent oxygen free radicals and peroxidation of lipids in the membrane of myocardial mitochondria, which results in suppression of DNA, RNA, and proteins; thereby causing altered adenylyl cyclase activity and disrupted calcium homeostasis (Romond et al., 2005). Cumulative doses are responsible for increasing the risk of anthracyclines-induced cytotoxicity.

Monoclonal antibodies (Mabs) are the main cause of type 2 damage. They are commonly used in the management of many types of cancer. Chemotherapy agents that can cause reversible cardiotoxicity are trastuzumab, lapatinib, sunitinib and bevacizumab. These anticancer agents can also cause hypertension. The mechanism could be by causing a decrease in vascular endothelial growth factor (VEGF) which in turn results in a reduction of nitric oxide (NO) in the arteriolar wall hence causing increased vascular resistance. In breast cancer, aggressive disease and a worse prognosis have been attributed to human epidermal growth factor receptor 2 (HER2)–positive receptors (Suter and Ewer, 2013). Csapo and Lazar (2014) reported in their review that trastuzumab, a humanized Mab, has shown a 50% reduction in recurrence rates and a 33% improvement in survival (Csapo and Lazar, 2014). Available data suggest that the cadiotoxicity induced by trastuzumab is as a result of blockage of HER2 receptors. HER2 receptors are important for embryonic cardiac development and for protection of the heart from cardiotoxins, hence they are present on cardiac myocytes (Groarke and Nohria, 2015). As a result, when the gene of these receptors are suppressed, dilated cardiomyopathy develops. This helps identify the difference between type 1 and type 2 cardiotoxicity; type 1 has a greater association with cardiac dysfunction and clinical heart failure (HF), and type 2 leads to an increased loss of contractility and less death of cardiomyocytes and can reverse (Suter and Ewer, 2013).

Suter and Ewer (2013) proposed a system to identify drugs that cause the different types of damage, and they defined cardiotoxicity as a serial decline in left ventricular ejection fraction (LVEF). The American Society of Echocardiography defined cardiotoxicity as an LVEF drop from >10% to <53%. The Cardiac Review and Evaluation Committee proposed a definition of left ventricular dysfunction (LVD) to be “a decline in cardiac LVEF; presence of symptoms of congestive heart failure (CHF); associated signs of CHF, including but not limited to S3 gallop, tachycardia, or both; and decline in LVEF of at least 5% to less than 55% with accompanying signs or symptoms of CHF, or a decline in LVEF of at least 10% to below 55% without accompanying signs or symptoms (Groarke and Nohria, 2015).

Many cancer survivors are living with long-term adverse effects of cancer therapy with pathological organ systems. Cardiovascular toxicity of anticancer drugs is one of the most life-threatening adverse effects. Several anticancer agents, such as anthracyclines (daunorubicin, doxorubicin, epirubicin, idarubicin), trastuzumab, cyclophosphamide, antimetabolites (cladribine, cytarabine, 5-fluorouracil), alkylating agents (busulfan, carboplatin, carmustine, chlormethine, cisplatin, cyclophosphamide, mitomycin), angiogenesis inhibitors, taxanes (docetaxel, cabazitaxel, paclitaxel), topoisomerase inhibitors (vinca alkaloids, etoposide, tretinoin,) and tyrosine kinase inhibitors (TKIs) have been linked with an increase in the risk of cardiovascular morbidity and mortality (Panjrath and Jain, 2007; Saif et al., 2009; Frickhofen et al., 2002; Cardinale et al., 2015; Rowinsky, et al., 1991; Dutcher, et al., 2001;Chu, et al., 2007).

Childhood cancer survivors face a high lifetime risk of late cardiovascular disease (Reulen et al., 2010; Lipshultz, et al., 2012). Patients with pre-existing cardiovascular diseases are at higher risk of cardiotoxicity compared to those that have healthy cardiovascular systems. The spectrum of cardiovascular complications of cancer therapy includes left ventricular (LV) dysfunction, congestive heart failure (CHF), coronary vasospasm, angina, myocardial infarction (MI), arrhythmias, systemic hypertension, pericardial effusion, pulmonary fibrosis and pulmonary hypertension (Schwartz et al., 2013). A newly emerging subspecialty known as cardio-oncology is designed to address the complex interaction between cancer and cardiovascular system through monitoring, early detection, prevention and treatment of cardiotoxicity of cancer therapies; development of newer therapies with lower or no cardiotoxicity; and careful planning of cancer therapy in patients with pre-existing cardiovascular disease to avoid overt cardiotoxicity and heart failure (Albini et al., 2010; Russell et al., 2016).

About 80% of worldwide populations depend on traditional medicines to meet their primary health-care needs (Ullah et al., 2010). Plants are primary sources of medicines, food, shelters and other items that are daily made use of by humans. Their stems, leaves, flowers, roots, fruits and seeds provide food for humans (Amaechi, 2009). Nigeria is not left out in the medicinal application of plants as plants are employed in Nigeria for the treatment of many kinds of disease conditions. Infact public opinion has it that nature has given the cure of every disease in one way or another (Tiwari et al., 2011). Pterocarpus santalinoides is one of such plant species used for the management and treatment of ailments (Iwu, 1993; Dieye et al., 2008). The people of South Eastern part of Nigeria use the leaves of this plant to prepare soup especially for women who just gave birth, the leaves are also used to treat gastro-intestinal diseases, diabetic syndrome and skin diseases (Anowi et al., 2012). In North Central Nigeria, the leaves of this plant are used in treatment of pain and inflammation of lower abdomen, stomach ache and other infectious diseases (Igoli et al., 2003). In India, fruit extracts of this plant are used traditionally in treating skin diseases, boils, fevers, headache, etc (Jain et al., 2013). The stem bark extracts of Pterocapus santalinoides were reported to have anti-diabetic, antibacterial and hepatoprotective activities (Jain et al., 2013).

Various parts of Pterocarpus santalinoides are employed in traditional medicine in many African countries, to treat an array of human ailments. The ethno-medical use of leaves of Pterocarpus santalinoides in the treatment of diarrhoea and other gastrointestinal disorders as well as its triglyceride and glucose lowering properties has been experimentally verified (Prado, 2000; Okpo et al., 2011). The leaves of Pterocarpus santalinoides have antimicrobial activity and contain phytochemicals such as alkaloids, tannins, saponins, terpenoids, flavanoids and anthraquinones which might be responsible for this activity (Ukwueze et al., 2018). Ethanol extract of the leaves of Pterocarpus santalinoides has been shown to significantly increase the levels of haematological parameters such as haemoglobin, packed cell volume and platelets (Offor et al., 2015). The leaves of Pterocarpus santalinoides are used in the treatment of skin diseases such as eczema, candidiasis and acne, the bark extracts are used in the treatment of diabetes, cough and sore (Osuagwu and Akomas, 2013; Igoli et al., 2005; Ama, 2010; Okwuosa et al., 2011). Methanol leaf extract of Pterocarpus santalinoides (MEPS) does not cause significant toxicity in albino rats, when administered for a short duration, rather long term therapy with the extract could precipitate liver and kidney damage (Madubuike et al., 2020).

1.2 Pterocarpus santalinoides

Plate 1.1: Pterocarpus santalinoides

Source: https://tropical.theferns.info

Pterocarpus santalinoides, of the Leguminosae: papilionoideae family is an evergreen tree with a dense crown of drooping branches as shown in Plate 1.1. It is essentially bi-continental in distribution being native to tropical Western Africa and South America (Prado, 2000) and usually called red sandal wood in English (Offor, et al., 2015). The plant grows in the bush in Nigeria and is known in various Nigerian vernaculars as nturukpa (Igbo); okumeze (Edo); nja (Efik); gbengbe (Yoruba); gunduru or gyadar kurmi (Hausa); maganchi (Nupe); ikyarakya or kereke (Tiv) (Odeh and Tor-Anyiin, 2014). A fully grown tree of Pterocarpus santalinoides is usually very tall about 9 -15 m tall, the trunk of the tree is up to 1 m in diameter and has a flaky bark, pinnate leaves (10–20 cm long) with 5–9 leaflets, the flowers are orange-yellow and produced in panicles; bears fruit in pods 3.5 - 6 cm long, with a wing extending three-quarters around the margin (Prado, 2000; Keay, 1989).

Taxonomy:

Domain: Eukaryot

Kingdom: Plantae

Subkingdom: viridaeplanntae

Phylum: Magnoliophyta

Subphylum: Euphyllophytina

Infraphylum: Radiatopses

Class: Magnoliopsida

Subclass: Rosidae

Superorder: Fabanae

Order: Fabale

Family: Fabaceae

Subfamily: Faboideae

Tribe: Dalbergieae

Genus: Pterocarpus

Specie: Pterocarpus santalinoides (ILDIS, 2005; WAC, 2008)

Synonym(s): Pterocarpus amazonicus Huber; Pterocarpus esculentus Schum. & Thonn.; Pterocarpus grandis Cowan; Pterocarpus michelii Britton.

Common names: (English): red wood sandal; (Hausa): gunduru, gyadar kurmi; (Igbo): nturukpa; (Yoruba): gbengbe; (Ibibio): mkpafere idim

Botanic description: the name Pterocarpus is derived from the Greek words ‘pteran’ meaning a wing and, ‘karpos’ meaning’ fruit. The specific epithet ‘santalinoides’ refers to its likeness to P. santalinus found in Asia. P. santalinoides is a shade tolerant tree commonly found along riverine forests in Africa and tropical South America. Pterocarpus santalinoides is a tree 9-12 m tall with thin and flaking bark, exuding drops of red gum. They possess compound leaves containing 5-9 leaflets. Their leaf stalks are slender, about 10-20 cm long, leaflet stalk stout 2-5 mm long. Their fruits are light brown pod of about 3.5-6 cm. Their flowers are orange-yellow with narrowly cup-shaped calyx and petals that are densely hairy on the outside (WAC, 2008).

Uses: The young shoots and leaves can serve as fodder for livestock, the leaves are eaten by humans as vegetable. The shoot of mature Pterocarpus santalinoides is a source of termite resistant wood and red gum can be obtained from the stem when given a cut. Tannins and dyes obtained from the bark can be used for dyeing. The leaves and tree bark are ethnomedically used for the treatment of several ailments such as skin disease, stomach ache, diarrheoa, diabetic syndrome, inflammation of the lower abdomen and infectious diseases (Prado, 2000; Okpo et al., 2011; Osuagwu and Akomas, 2013; Igoli et al., 2005; Ama, 2010; Okwuosa et al., 2011). This plant is an important species for soil conservation in water catchment areas and good source of shade around settled areas and farms where it provides protection from wind. The nitrogen fixing activity in its root nodules coupled with the decomposition of its leaf litter improves soil fertility. The plant is used as an ornamental tree and its poles have been used for fencing (Orwa et al., 2009). Its flowers can also provide ecstatic view beautifying the environment (WAC, 2008). It has been listed among the species threatened by extinction (IUCN, 2023).

1.3 SCOPE OF THE STUDY

This study is limited to:

i. Collection and preparation of leaves of Pterocarpus santalinoides

ii. Preparation of ethanol crude extract of the leaves

iii. LD50 Determination of the ethanolic crude extract

iv. Qualitative phytochemistry

v. Collection and weighing of the experimental animals.

vi. Daily administration of standard drugs and extract to the animals.

vii. Induction of cardiac injury using 5-fluorouracil

viii. Sacrificing of experimental animals for collection of sera, blood and heart samples

ix. Assay of lipid profile

x. Assay of troponin

xi. Assay of haematological indices

xii. Assay of creatine kinase (CK-MB)

xiii. Histological studies of the hearts

xiv. Fractionation of the ethanol crude extract into n-butanol, ethyl acetate and chloroform fractions

xv. Treatment of animals using the different fractions and standard drug

xvi. Induction of cardiac injury using 5-fluorouracil

xvii. Sacrificing of the animals

xviii. Evaluation of the cardiac function biomarkers: lipid profile, troponin, CK-MB

xix. Assay of oxidative status biomarkers: Malondialdehyde (MDA), glutathione peroxidase (GSPx), superoxide dismutase (SOD), catalase (CAT)

xx. Assay of renal function biomarkers: Electrolytes, urea and creatinine

xxi. Assay of liver function biomarkers: Alkaline phosphatase (ALP), aspartate amino transferase (AST) and alanine amino transferase (ALT) activities

xxii. Haematological indices determination

xxiii. Histopathological studies of their hearts, livers and kidneys

1.4 STATEMENT OF PROBLEM

Several important therapeutic agents have been linked with risks of cardiotoxicity, for example most anti-cancer agents have been proven to precipitate this ugly side effect. Treatment of disease conditions is a major way of reducing casualties and mortalities from these diseases. Side effect is a phenomenon common to most drugs and considering the expediency of these therapeutic agents, it becomes necessary to come up with an additional substance that can confer a protective effect on the heart from the cardiotoxicity potential of these chemotherapeutic agents and that is why we chose to study the effectiveness of the leaves of Pterocarpus santalinoides in this regard.

Pterocarpus santalinoides is a tropical flowering tree that is widely distributed in Nigeria and in other tropical countries such as Cameroon, Ghana, Senegal and Brazil. It has many applications as earlier mentioned but our interest bothers around the medicinal uses. In the South Eastern part of Nigeria, the leaves are used to cure gastro-intestinal diseases, diabetic syndrome and skin diseases (Anowi et al., 2012; Ama, 2010; Osuagwu and Akomas, 2013). In North Central part of Nigeria, the leaves are used to treat lower abdominal pain and inflammation, stomach ache and other infectious diseases (Igoli et al., 2005). In India, fruit extracts are used traditionally for the treatment of skin diseases, boils, fevers, headache, etc. The stem bark extracts were reported to have hepatoprotective, antibacterial and anti-diabetic activities (Jain et al., 2013). The ethnomedicinal use of leaves of Pterocarpus santalinoides in the treatment of diarrhea and in lowering blood triglyceride and glucose levels has been experimentally verified (Iwu, 1993; Ojiako and Nwanjo, 2006). It is believed that nature has provided the cure of every disease in one way or another (Okpo et al., 2011). Hence, this research was carried out in other to experimentally verify if the ethanol leaf extract of this plant could have a cardioprotective impact on 5-fluouracil induced cardiotoxicity in wistar rats which could provide insight on the possibility of using it as porphylatic substance that could be used by cancer patients undergoing chemotherapy to prevent cardiotoxicity side effects of the anti-cancer drugs.

1.5 JUSTIFICATION OF THE STUDY

Among other health benefits attributed to the various parts of Pterocarpus santalinoides, is its ability to lower blood LDL-cholesterol and enhance its HDL-cholesterol level, factors which are important indices for measuring cardiovascular health, this effect has been experimentally verified (Ihedioha et al., 2018; Okwuosa et al., 2011). In a similar vein, the authenticity of the cardiotoxicity risk of many chemotherapeutic agents most especially as it applies to anti-cancer drugs is non – negotiable and an existing fact. Therefore, considering the expediency of these therapies and the lethality of the cardiotoxicity potential, it will be more beneficial to identify another harmless but cardioprotective substance that would be administered to patients before subjecting them to chemotherapy. This could be done in order that the additional substance can help prevent or significantly reduce the cardiotoxicity potential of these very important therapeutic agents. This will in turn prevent the prohibition of the sale or use of such drugs on account of the lethal risks associated with them, but will encourage their continued usage in as much as the heart and the components of the cardiovascular system are appreciably protected from their harmful effects. Because of the aforementioned medicinal uses of the leaves of Pterocarpus santalinoides, it became expedient to subject its possible cardioprotective potential against 5-fluorouracil induced cardiotoxicity to experimental scrutiny and verification. With the aim that if it comes out very effective compared to aspirin (a known cardioprotective drug), and considering the low toxicity profile of the tender leaves of this plant, it may be a preferred adjuvant to chemotherapeutic agents which can protect the heart of the cancer patients from the cardiotoxicity adverse effects of such drugs.

1.6 RELEVANCE OF THE STUDY

The assessment of the cardio-protective potential of ethanol leaf extract and fractionated products of Pterocarpus santalinoides is necessary because of the following reasons:

1. It will reveal if the crude ethanol leaf extract of the Pterocarpus santalinoides has cardioprotective protective potential on patients on 5-fluoracil

2. It will reveal whether or not the fractionated version of the extract will have stronger cardioprotective potential on the wistar rats than the crude extract

3. It will show whether or not the crude ethanol leaf extract and the fractionated portions of the extract will have stronger cardioprotective potential on the wistar rats than aspirin

4. It will reveal the harmful effects 5-fluorouracil treatment on the heart, liver and kidneys as well the protective effect of the ethanol leaf extract against these toxicities.

5. This study will reveal the possible mechanism of cardiotoxicity of 5-fluorouracil as well as the probable mechanism of cardioprotectiveness of ethanol leaf extract and their n-butanol, ethyl-acetate and chlroform fractions.

1.7 AIM OF THE STUDY

The aim of this study is to assess the cardioprotective potentials of the ethanol leaf extracts and fractions of Pterocarpus santalinoides in Wistar rats.

1.8 OBJECTIVES OF THE STUDY:

Specifically, the study sought to:

i. Carry out qualitative phytochemical screening of the crude ethanol leaf extract

ii. Determine the LD₅₀of the crude ethanol leaf extract in albino mice

iii. Determine cardiovascular indices (serum troponin concentration and CK-MB Activity)

iv. Determine serum lipid profile (TC, LDL-C, HDL-C, VLD-C and TG)

v. Determine haematological indices

vi. Determine cardiovascular risk index

vii. Determine liver function status (serum ALP, ALT and AST activity)

viii. Determine kidney function status (serum electrolytes, urea and creatinine levels)

ix. Determine levels of oxidative damage (serum malonyldialdehyde levels)

x. Determine serum activities of antioxidant enzymes (SOD, CAT, GSPx)

xi. Carry out histopathological evaluations of the organs (heart, liver and kidney)

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