ABSTRACT
Inflammation, diarrhea, and microbial infections produce high morbidity and mortality globally, contributing to a high burden of disease in developing countries. Despite the utilisation of conventional drugs to treat inflammation, diarrhea, and microbial infections, their inaccessibility, unaffordability and their side effects hinder the successful treatment and alleviation of disease. The emergence of antimicrobial-resistant bacteria and fungi strains have compromised the efficiency of antimicrobial chemotherapy, which leads to undesirable sequalae. There is an urgent need to search for alternative therapies, which are efficacious, affordable, accessible and safe in order to alleviate human suffering and promote the quality of life. Medicinal plants present a feasible alternative source of potent pharmacological molecules, which are affordable, easily accessible and safe due to the many biologically active phytochemicals they have. Although medicinal plants have been used by humans for ages as medicines and food, only a few have been empirically investigated. Cucumis dipsaceus has a long history of ethnomedicinal usage in treating inflammation, diarrhea, and microbial infections, in Kenya and other countries. However, there is scanty empirical data to validate its efficacy and safety. The anti-inflammatory antidiarrhea, antimicrobial, and toxic effects of methanolic and aqueous leaf and fruit (methanolic and aqueous leaf and fruit) extracts of C. dipsaceus were investigated. The in vivo anti-inflammatory activities of the methanolic and aqueous leaf and fruit extracts of C. dipsaceus were studied using the formalin-induced paw oedema technique in Wistar rats. The castor oil-induced diarrhea method was used to determine the antidiarrhea activity of the methanolic and aqueous leaf and fruit extracts of the studied plant in Wistar rats. Isolated rabbit ileum was used to determine the effects of the C. dipsaceus extracts on the gastrointestinal motility. Antimicrobial activity of the methanolic and aqueous leaf and fruit extracts was determined using the disk diffusion and broth microdilution techniques described previously. The acute oral and dermal toxicity effects of the methanolic and aqueous leaf and fruit extracts of C. dipsaceus were studied in rabbits and rats, respectively, using appropriate guidelines. Data was analysed using GraphPad Prism statistical software version 9.1. The results indicated significant reductions in formalin-induced paw oedema in the Wistar rats by methanolic and aqueous leaf and fruit extracts of C. dipsaceus, in a dose- and time-dependent manner (P<0.05), with percentage inhibition of between 1.56% and 97.59%. Methanolic and aqueous leaf and fruit extracts of C. dipsaceus significantly (P<0.05) inhibited diarrhea and intestinal motility in Wistar rats and rabbits respectively, in a dose-dependent manner, thereby depicting their antidiarrhea effects. Furthermore, the methanolic and aqueous leaf and fruit extracts of C. dipsaceus significantly inhibited the growth of P. aeruginosa, S. enteriditis, E. coli, C. albicans, and B. subtilis in varying degrees as depicted by the different growth inhibition zones of between 6 mm and 20 mm and the Minimum Inhibitory Concentrations of
3.125 µg/ml. The observed anti-inflammatory, antidiarrhea, and antimicrobial activities of the plant extracts were attributed to various phytochemicals extractable by water and methanol, which exerted pharmacological efficacy via various mechanisms. Moreover, aqueous and the methanolic and aqueous leaf and fruit extracts of C. dipsaceus showed no observable acute dermal toxicity effects on the abraded and intact skins of New Zealand White rabbits. Similarly, the methanolic and aqueous leaf and fruit extracts of C. dipsaceus showed no observable acute oral toxicity during the 14-day experimental period. In conclusion, the extracts were considered safe according to the OECD Guidelines. Further pharmacological and toxicological investigations of the tested plant extracts using more advanced techniques should be done in order to elucidate and optimise bioactive molecules for treating inflammation, diarrhea, and microbial infections.
TABLE OF CONTENTS
TITLE i
DECLARATION ii
DECLARATION OF ORIGINALITY iii
DEDICATION iv
ACKNOWLEDGEMENTS v
LIST OF TABLES ix
LIST OF FIGURES x
LIST OF APPENDICES xi
LIST OF PLATES xii
ACRONYMS AND ABBREVIATIONS xiii
ABSTRACT xv
CHAPTER ONE
INTRODUCTION
1.1 Background Information 1
1.2 Problem statement and justification 3
1.3 Study objectives 5
1.3.1 General objective 5
1.3.2 Specific objectives 5
1.4 Research questions 6
CHAPTER TWO
LITERATURE REVIEW
2.1 Inflammation, microbial infections and diarrhea 7
2.1.1 Inflammation 7
2.1.2 Microbial infections 8
2.1.3 Diarrhea 9
2.2 Conventional management of inflammation, microbial infections, and diarrhea 9
2.3 Herbal Management of Inflammation, Microbial infections, and Diarrhea 12
2.4 Cucumis dipsaceus 13
2.4.1 Botanical classification 13
2.4.2 Description and distribution 13
2.4.3 Ethno-medicinal uses of C. dipsaceus 14
2.4.4 Phytochemistry and biological activity of C. dipsaceus 14
CHAPTER THREE
MATERIALS AND METHODS
3.1 Collection and preparation of plant materials 15
3.2 Extraction methods 17
3.2.1 Methanolic extraction procedure 17
3.2.2 Aqueous extraction procedure 17
3.3 Experimental animals 17
3.3.1 Preparation of experimental dosages 18
3.4 Investigation of acute toxicity effects of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus 19
3.4.1 Acute oral toxicity effects of the studied plant extracts in Wistar rats 19
3.4.2 Acute dermal irritation /corrosion test on New Zealand White rabbits 19
3.5 Anti-inflammatory activity of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus in Wistar rats 20
3.6 Determination of the effects of the aqueous and methanolic leaf and fruit extracts of
C. dipsaceus on gastrointestinal motility 21
3.6.1 Determination of antidiarrhea activity of the studied plant extracts in Wistar rats .21
3.6.2 Determination of the effects of the plant extracts on intestinal contraction of isolated rabbit ileum 23
3.7 Determination of the antimicrobial activity of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus 23
3.7.1 Microbial strains 23
3.7.2 Preparation and standardisation of microbial inocula 23
3.7.3 Preparation of extracts 24
3.7.4 The disc diffusion assay 25
3.7.5 Determination of Minimum Inhibitory Concentration 25
3.8 Statistical management and data analysis 26
3.9 Ethical considerations 27
CHAPTER FOUR
RESULTS
4.1 Anti-inflammatory activity of aqueous and methanolic leaf and fruit extracts of C. dipsaceus in Wistar rats 28
4.2 Antimicrobial effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus
on selected bacteria and candida albicans 30
4.3 Effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus on gastrointestinal motility in Wistar rats 36
4.3.1 Inhibition of diarrhea in castor oil-induced diarrhea in Wistar rats 36
4.3.2 Effects of the methanolic leaf and fruit extracts of C. dipsaceus on gastrointestinal contraction of isolated rabbit ileum 42
4.4 Acute toxicity effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus
in Wistar rats and New Zealand White rabbits 43
4.4.1 Acute dermal toxicity effects of the tested plant extracts on New Zealand White rabbits 43
4.4.2 Acute oral toxicity effects of the plant extracts in Wistar rats 45
CHAPTER FIVE
DISCUSSION, CONCLUSION AND RECOMMENDATIONS
5.1 Discussion 47
5.2 Conclusion 56
5.3 Recommendations 56
REFERENCES 58
APPENDICES 81
LIST OF TABLES
Table 3.1: Experimental design for the investigation of the anti-inflammatory activity of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus in Wistar rats 21
Table 3.2: Experimental design for the investigation of the antidiarrhea activity of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus in Wistar rats 22
Table 4.1: Anti-inflammatory activity of aqueous and methanolic leaf and fruit extracts of C. dipsaceus in Wistar rats 30
Table 4.2: Antimicrobial effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus on S. enteriditis 31
Table 4.3: Antimicrobial effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus on E. coli 32
Table 4.4: Antimicrobial effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus on P. aeruginosa 33
Table 4.5: Antimicrobial effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus on B. subtilis 34
Table 4.6: Antimicrobial effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus on C. albicans 35
Table 4.7: Minimum Inhibitory Concentrations of aqueous and methanolic leaf and fruit extracts of C. dipsaceus 36
Table 4.8: Effects of methanolic leaf and fruit extracts of C. dipsaceus on gastrointestinal contraction frequency of isolated rabbit ileum 43
Table 4.9: Acute dermal toxicity effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus on New Zealand White rabbits 44
Table 4.10: Acute oral toxicity effects of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus in Wistar rats 46
LIST OF FIGURES
Figure 4.1: Percentage inhibition of diarrhea by the aqueous fruit extracts of C. dipsaceus in castor oil-induced diarrhea in Wistar rats 37
Figure 4.2: Percentage inhibition of diarrhea by the aqueous leaf extracts of C. dipsaceus in castor oil-induced diarrhea in Wistar rats 38
Figure 4.3: Percentage inhibition of diarrhea by the methanolic fruit extract of C. dipsaceus in castor oil-induced diarrhea in Wistar rats 39
Figure 4.4: Percentage inhibition of diarrhea by the methanolic fruit extract of C. dipsaceus in castor oil-induced diarrhea in Wistar rats 40
Figure 4.5: Comparison among the percentage inhibition of diarrhea exhibited by the aqueous and methanolic extracts of C. dipsaceus in castor oil-induced diarrhea in Wistar rats. 42
LIST OF APPENDICES
Appendix I: Ethical Approval by the Faculty Biosafety, Animal Use and Ethics Committee 81 Appendix II: Botanical identification of the study plant by the botany Department of National Museums of Kenya 82
Appendix III: Research permit granted by the National Commission for Science, Technology and Innovation 83
Appendix IV: Plagiarism test report 84
Appendix V: Published Research article based on this thesis 85
LIST OF PLATES
Plate 1a: A photograph showing a maturing fruit of Cucumis dipsaceus 16
Plate 1b: A photograph showing a flower and climbing tendrils of Cucumis dipsaceus 16
Plate 1c: A photograph showing leaves of Cucumis dipsaceus 16
Plate 1d: A photograph of the Researcher (Dr. Purity Kimathi) and Herbalist harvesting leaves and fruits of Cucumis dipsaceus 16
ACRONYMS AND ABBREVIATIONS
ANOVA Analysis of variance
AQF Aqueous Fruit Extract
AQL Aqueous Leaf Extract
BAUEC Biosafety, Animal use and Ethics Committee
BW Body weight
CDC Centre for Disease control
CFU Colony Forming Unit
CGR Control Group of Rats
CLSI Clinical and Laboratory Standard Institute
DMSO Dimethyl sulphoxide
DPHPT UoN Department of Public Health, Pharmacology and Toxicology, University of Nairobi
EGR Experimental Group of Rats
GPS Global positioning System
HPLC High Performance Liquid Chromatography
Hrs Hours
Kg Kilogram
LD50 Median Lethal dose
MDR Multi Drug Resistant
MEOHF Methanolic Fruit Extract
MEOHL Methanolic Leaf Extract
MHA Mueller Hinton Agar
MICs Minimum Inhibitory Concentrations
MSDS Material Safety and Data Sheets
N Sample size
NACOSTI National Commission for Science, Technology and Innovation
NSAIDs Non- Steroidal anti-inflammatory drugs
OECD Organisation for Economic Co-operation Development
SDA Sabouraud Dextrose Agar
SEM Standard Error of the Mean
UDP Up -Down-Procedure
WHO World Health Organisation
CHAPTER ONE
INTRODUCTION
1.1 Background Information
Traditional medicine has been practiced for ages, even before the emergence of modern medicine (Sofowora et al., 2013). Previously, herbalism was based on crude preparations in order to manage various diseases, however, with the advent of modern technology, various plant-derived drugs have been developed to present-day drugs such as creams, ointments, injections, capsules, and Tablets (Ozioma and Chinwe, 2019; Mahomoodally, 2013). Although conventional drugs were developed for various diseases, the usage of medicinal plants in order to treat various diseases is still dominant, due to their easy availability, accessibility, and relative affordability, especially in sub-Saharan Africa (James et al., 2018). The World Health Organization (WHO) reported that more than 80% of people, especially in the low and medium income countries, depend on traditional medicine with over 85 % of the medicines being derived from plant extracts (WHO, 2018). Traditional medicine is very common in Kenya, with various ethnic communities utilising plant-based remedies in order to prevent and treat diseases (Kigen et al., 2016, 2019; Kipkore et al., 2014). Herbal medicines are relatively cheap, accessible and cause minimal side effects (Nasri and Shirzad, 2013).Despite the prominence of herbal medicine, documented empirical data on their efficacy, phytochemical composition, mechanisms of action, and toxicity profile is still scarce.
Despite the extensive uses of medicinal plants for the alleviation of pain and inflammation management, they are excluded from conventional healthcare plans (Alemu et al., 2018). Phytochemicals can offer novel compounds of therapeutic value; hence, there is need for their empirical characterisation.
Inflammation is an immune response, which is often non-specific, and is evoked after injury, pathogenic invasion, chemical irritation, or allergy (Ptaschinski and Lukacs, 2018). The process involves recognition of injury or pathogen, activation of mediators, recruitment of defence cells, breakdown of diseased tissues, and promotion of tissue repair. Sometimes, inflammation persists due to defects in the body’s defence system, thus exacerbating the associated syndrome’s sequelae (Chen et al., 2018; Hunter, 2012).
Antimicrobial molecules are crucial in lowering the burden of communicable diseases affecting the world population (Abbafati et al., 2020a; Christou, 2011). However, availability of fewer, or the lack of efficacious antimicrobial agents which can thwart resistant pathogenic strains poses a great public health problem worldwide (Dadgostar, 2019; Frieri et al., 2017). In the view of rapidly emerging isolates of resistant strains, development of effective agents is critical. Notably, the history of new antimicrobials is tainted with rapid emergence of resistance, further dimming the hope for long term effectiveness of the current therapeutic agents (Ayukekbong et al., 2017; Manandhar et al., 2019). Scientists need to continuously explore the derivates of medicinal plants that contain useful secondary metabolites such as alkaloids, tannins, flavonoids and phenolic compounds that contain anti-inflammatory, antioxidant and antimicrobial properties (Kathare et al., 2021a; Nyarang and Bonareri, 2021; Obey et al., 2016; Scalbert, 1991).
Cucumis dipsaceus has been used widely to manage inflammation and pain, and in the treatment of bacterial infections, among other functions, including consumption as food (Kipkore et al., 2014; Mutie et al., 2020; Tefera and Kim, 2019). Previous research indicate that leaf extracts of C. dipsaceus have antimicrobial activity (Shivakoti et al., 2015), and various parts including fruits possess anti-inflammatory, analgesic, diuretic, anti-dysentery, among other properties (Kaur and Lata, 2019). In Kenya, a concoction of boiled roots is used to treat abdominal pains among the Keiyo residents (Kigen et al., 2014). The present study explored anti-inflammatory, antimicrobial, antidiarrhea, and toxic effects of the methanolic and aqueous leaf and fruit extracts of C. dipsaceus.
1.2 Problem statement and justification
Inflammatory diseases cause debilitating physical, psychological, and economic effects, to the affected patients, globally, with the highest burden lying in the less developed Nations, especially in sub-Saharan Africa (Abbafati et al., 2020a, 2020b; Alema et al., 2020; Henschke et al., 2015; Jairath and Feagan, 2020). Microbial infections of the gastrointestinal tract, cause gastric irritation, inflammation, and impaired gastric functioning, manifesting in abdominal discomfort and diarrhea (CDC, 2015; Christou, 2011; Troeger et al., 2017). Diarrhea is among the leading causes of morbidity and mortality worldwide especially in the children, elderly, and immunocompromised persons (CDC, 2015).
Despite the availability of conventional anti-inflammatory, antimicrobial, and antidiarrhea drugs, inflammatory disorders, microbial infections, and diarrhea still continues to pose global Public health problem (Alatab et al., 2020; Centers for Disease Control and Prevention, 2015; Jairath and Feagan, 2020; Mathers, 2017). The available anti-inflammatory drugs are associated with adverse effects, following chronic use (Monteiro and Steagall, 2019). For instance, the commonest anti-inflammatories cause gastrointestinal bleeding, intestinal perforations, indigestion, constipation, hepatotoxicity, nephrotoxicity, cardiotoxicity, among other side effects (Felson, 2016; Harirforoosh et al., 2013; Moriasi et al., 2021).
The emergence of antimicrobial resistant strains of bacteria and fungi, has complicated successful use of chemotherapy (Ayukekbong et al., 2017).The anti-inflammatory agents used now, cause undesirable effects, including constipation, gastric irritation, cardiotoxicity, hepatotoxicity, nephrotoxicity, low efficacy among others (Caldwell and Cluff, 1974; Dadgostar, 2019; Fernebro, 2011; Mahmoud abd El-Baky, 2016; Mohsen et al., 2020; Shehab et al., 2016). Antidiarrhea drugs are associated with constipation, impaired gastric motility, among other life-threatening effects (WHO, 1990; Dosso et al., 2012; Niemegeers et al., 1981; Sisay et al., 2017).
Conventional anti-inflammatory, antimicrobial, and antidiarrhea drugs are costly, inaccessible, and unavailable, especially in rural areas of developing Countries, where over 80 % of the global burden of diseases lies, due to inadequate, and insufficient healthcare systems, and resources (Mathers, 2017; Murray and Lopez, 1996; WHO, 2020). Therefore, alternative drug agents, which are safe, efficacious, affordable, easily accessible are required to avert human suffering, are required especially in the developing Nations.
Medicinal plants present a viable source of potent therapies against inflammation, microbial infections, and diarrhea, among other diseases, due to their rich ethnomedical history of application, and the diverse array of bioactive principles they contain (Kathare et al., 2021; Moriasi et al., 2021). However, only few medicinal plants have been empirically investigated and validated for use against the ailments they are traditionally used to treat. Moreover, herbal medicines are preferred because of their affordability, availability, ease of usage, ability to treat multiple conditions, and their minimal adverse effects.
Despite the widespread applications of plant-based ethnomedicines to treat diseases, various safety concerns have been raised (George, 2011). This is due to the lack of standard preparation guidelines, specific dose regimens for each disease, appropriate labelling and marketing, empirical Pharmacological, Toxicological and safety profile data, and regulations governing the practice (Abdullahi, 2011; George, 2011; Kaur et al., 2013; Zhang et al., 2012). Therefore, empirical pharmacologic investigations and safety evaluations of herbals may foster the elucidation of efficacious and safe therapies, against various diseases, especially those which are associated with inflammation, microbial infections, and diarrhea, which negatively impact human health.
Despite the utilisation of C. dipsaceus in traditional medicine in order to manage inflammatory, microbial, and diarrhea associated diseases (Kareru et al., 2007; Kigen et al., 2014; Mutie et al., 2020; Njoroge and Newton, 1994), there is scanty empirical evidence to back the claimed Pharmacologic efficacy and safety. This study investigated the anti- inflammatory, antimicrobial, antidiarrhea and toxic effects of methanolic and aqueous leaf and fruit extracts of C. dipsaceus to lay a framework towards validation of their usage, and the development of potent, safe, accessible, and affordable therapies.
1.3 Study objectives
1.3.1 General objective
i. The main objective of the study was to investigate the anti-inflammatory, antimicrobial, antidiarrhea, and toxic effects of the aqueous and methanolic leaf and fruit extracts of Cucumis dipsaceus Wistar rats and New Zealand White rabbits.
1.3.2 Specific objectives
The following were the specific objectives of the study:
i. To determine the anti-inflammatory activity of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus in formalin-induced oedema in Wistar rat model.
ii. To investigate the antidiarrhea effects of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus in castor oil-induced diarrhea in Wistar rats and New Zealand White rabbits.
iii. To determine the antimicrobial effects of the aqueous and methanolic leaf and fruit extracts of C. dipsaceus on selected enteric bacteria and candida albicans.
iv. To investigate the acute oral and dermal toxicity effects of aqueous and methanolic leaf and fruit extracts of C. dipsaceus using Wistar rats and New Zealand White rabbits.
1.4 Research questions
This study was guided by the following research questions:
i. Do the aqueous and methanolic leaf and fruit extracts of C. dipsaceus have anti- inflammatory activity in formalin-induced oedema in Wistar rat model?
ii. Do the aqueous and methanolic leaf and fruit extracts of C. dipsaceus have antidiarrhea activity in castor oil-induced diarrhea in Wistar rat and New Zealand White rabbit models?
iii. Do the aqueous and methanolic leaf and fruit extracts of C. dipsaceus have anti- microbial activity against select enteric bacteria and candida albican strains?
iv. Do the aqueous and methanolic leaf and fruit extracts of C. dipsaceus cause acute oral and dermal toxicity effects in Wistar rats and New Zealand White rabbits?
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