TABLE OF CONTENTS
Title Page
Table of Contents
Abstract
CHAPTER ONE
1.0 INTRODUCTION
1.1Statement of Research Problems
1.2 Justification
1.3 Research Hypothesis
1.4 Aim and Objectives
CHAPTER TWO
2.0 LITERATURE REVIEW
2.1 Learning and Memory
2.2 Short-Term Memory
2.3 Long-Term Memory
2.3.1 Declarative Memory
2.3.2 Implicit Memory
2.4 Spatial Cognition
2.5 Memory Enhancers
2.6 Academic Doping
2.7 Synaptic Plasticity
2.7.1 Biochemical Mechanism of Synaptic Plasticity
2.8 Date Palm Fruit (Phoenix dactylifera)
2.9 Date Palm Fruits and Cognition
2.10 Date Palm Fruits and Other Components of Nervous System
CHAPTER THREE
3.0 MATERIALS AND METHODS
3.1 Animals
3.3 Drug Preparation
3.4 Neurobehavioral Assay
3.4.1 Morris Water Maze
3.4.2 Elevated Plus Maze for Memory
3.4.3 Barnes Maze
3.5 Biochemical Analysis
3.5.1 Brain Tissue Preparation
3.5.2 Acetylcholinesterase Assay Kit
3.5.3 Acetylcholinesterase Assay
3.6 Statistical Analysis
CHAPTER FOUR
4.0 RESULTS
4.1 Assessment of Visio-Spatial Long Term Memory using Morris Water Maze
4.2 Assessment of Visio-Spatial Long Term Memory using Elevated Plus Maze
4.3 Assessment of Visio-Spatial Long Term Memory using Barnes Maze
4.4 Acetylcholinesterase Enzyme Activity
4.4.1 Acetylcholinesterase Enzyme Activity of Mice Used in Morris Water Maze
4.4.2 Acetylcholinesterase Enzyme Activity of Mice Used in Elevated Plus Maze
4.4.3 Acetylcholinesterase Enzyme Activity of Mice Used in Barnes Maze
CHAPTER FIVE
5.0 DISCUSSION
CHAPTER SIX
6.1 Summary
6.2 Conclusion
6.3 Recommendations
6.4 Contribution to Knowledge
REFERENCES
Appendices
Abstract
Phoenix dactylifera fruits possess essential properties such as analgesic,
antioxidant, and nephroprotective activity but there is paucity of
information on researches centered on the benefits of Phoenix dactylifera
in learning and memory. This study was designed to evaluate the effects of Phoenix
dactylifera fruit extract on spatial learning and memory using
neurobehavioral paradigms of Morris water, Barnes, and elevated plus mazes as
well as evaluation of acetylcholinesterase enzyme activity of the brain tissues
of the mice studied. Seventy five mice of both sexes were used for the study
and divided into five groups of 5 mice each. Group 1 (distilled water 10 ml/kg)
served as control, group 5 (Piracetam 100 mg/kg) served as positive control.
Groups 2-4 were treated withPhoenix dactylifera extract 1000, 500 and
250 mg/kg respectively. Treatment with aqueous extract of Phoenix
dactylifera and Piracetam was done 1 hour prior to the experiment daily for
three days (in Morris water and Barnes mazes) and two days (in elevated plus
maze). Results obtained from this study revealed that Phoenix dactylifera
fruit (1000 mg/kg) impaired learning of mice in Morris water maze (p<0.05),
but did not impair memory in Morris water maze, Barnes maze and elevated plus
maze. No statistically significant difference was seen between control group
and Phoenix dactylifera treated groups in acetylcholinesterase activity
in Morris water, Barnes and elevated plus mazes, but statistically significant
difference exist between control group and Piracetam treated group in
acetylcholinesterase activity (p>0.05). No strong correlation was observed
between probe parameters of neurobehavioral paradigms (frequency of platform
crossings, retention and correct head dips in Morris water, Barnes and elevated
plus mazes respectively) and acetylcholinesterase activity. Acute treatment
with aqueous extract of Phoenix dactylifera fruit impaired learning in Morris
water maze and has no effect on memory in Morris water, Barnes and elevated
plus mazes.
Key words: Phoenix
dactylifera, Piracetam, Cognition, Acetylcholinesterase
enzyme, Learning and Memory.
CHAPTER ONE
1.0 Introduction
One of the major functions of the brain is the flexible adaptation to our ever-changing environment. The brain possesses executive circuits which do not only monitor and maintain current behavioral goals but also incorporate new goals and rules. This updating can come in the form of a quick integration of previously acquired knowledge when a well-known stimulus informs an animal of a change in reward contingencies. Hence, such updating requires new learning.Higher cognitive abilities evolved largely in mammals (Victoria et al., 2014).
Cognitive neuroscientists consider memory as the retention, reactivation, and reconstruction of the experience-independent internal representation (Schwabe and Wolf, 2010). The major challenge of neuroscientists today is identifying therapies or mechanisms that can treat or reverse the effects of memory complaints and other neurodegenerative disorders. Date palm (known as Phoenix dactylifera) has been used intreatment of various nervous disorders and memory complaint (Vyawahare et al., 2009), such as Parkinson‘s disease via acting as dopamine agonist
(Ali et al., 2014), Alzheimer‘s and Vascular dementiavia its protective role in cerebral hypoperfusion (Rohini et al., 2014).
Brain areas involved in the neuroanatomy of memory include the hippocampus, the amygdala, the striatum, or the mammillary bodies which are thought to be involved in specific types of memory. For example, the hippocampus is believed to be involved in spatial learning and declarative learning, while the amygdala is thought to be involved in emotional memory (Labark and Cabeza, 2006). Prefrontal cortex and basal ganlia play vital role in storing working memory (Fiona and Torkel, 2008). The mechanism via which basal ganglia store working memory might.....
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