ABSTRACT
Data on the current levels of
sodium consumption of Nigerian adults are urgently needed to determine the contribution
of dietary sodium as a risk factor in the increasing incidence of hypertension
and related complications in the country. The aim of this study was to estimate
the daily salt intake of healthy ambulant Nigerian adults using the 24-hour
urinary sodium ion excretion method (the gold standard) and spot urine sodium
ion excretion method (a proposed convenient alternative). Eighty adult
Nigerians aged between 20 and 50 years made up of 60% males and 40% females
were the subjects that provided 24-hour urine and spot urine samples. Urinary
sodium excretion was estimated using the atomic absorption spectrophotometer
(AAS). Measured 24-hour urinary sodium excretions for male and female subjects
were 4.7+0.5 and 4.0+0.6 g/day respectively. This translates to a
dietary salt intake of 11.8+1.3 g/day for male subjects and 10.1+1.5
g/day for female subjects. A significant decrease (p<0.01) was observed
between the values obtained by 24-hour urinary sodium excretion method and spot
urinary sodium excretion method. Estimated 24-hour urinary sodium ion excretion
positively correlated (r=+61) with spot urinary sodium excretion. Age
dependent increase was observed in both measured and estimated 24-hour urinary
sodium ion excretion. Systolic and diastolic blood pressure increased
significantly (p<0.05) with increase in measured 24-hour urinary sodium ion
excretion. Based on these results, the salt intake of all the subjects as
determined by both methods far exceeded the recommended daily salt limit of
< 5.0g/day. The positive correlation (r= +0.61) between the results
obtained from both methods suggests that notwithstanding the differences
between the values obtained, the spot urinary excretion method can be used to
determine the daily dietary salt intake of Nigerians.
TABLE OF CONTENTS
Title Page
Abstract
Table of Contents
List of Figures
List of Tables
List of Abbreviations
CHAPTER ONE: INTRODUCTION
1.1 Sodium
1.1.1 Source of dietary sodium in the body
1.1.2 Significance of sodium
1.1.3 Physiological role of sodium
1.1.4 Health effect of sodium
1.2 Blood pressure
1.2.1 Cardiovascular disease
1.2.2 Stroke
1.3 Risk factors of hypertension
1.3.1 Age and gender
1.3.2 Genetics
1.3.3 Diet and weight
1.3.4 Obesity and body mass index
1.3.5 Consumption of food high in sodium
1.3.6 Alcohol consumption
1.3.7 Smoking
1.3.8 Lack of activity
1.3.9 Co-morbidity
1.4 Mediating factors for hypertension
1.4.1 Economic factor
1.4.2 Stress and personality
1.4.3 Hypertension medication
1.4.3.1 Diuretics
1.4.3.2 Adrenergic inhibitors
1.4.3.3 Vasodilators
1.5 Management of hypertension
1.5.1 Lifestyle modifications
1.5.2 Weight loss
1.5.3 Exercise
1.5.4 Dietary sodium reduction
1.5.5 Reduction in alcohol intake and smoking
1.6 Complimentary therapies
1.6.1 Foot reflexology
1.6.2 Effect of food reflexology on hypertension
1.6.3 Effect on anxiety and pain
1.6.4 Foot message
1.7 Aim and objectives of the Study
1.7.1 Aim of the Study
1.7.2 Specific objectives of the Study
CHAPTER TWO: MATERIALS AND METHODS
2.1 Materials
2.1.1 Subjects
2.1.2 Inclusion criteria
2.1.3 Instrument/Equipments
2.1.4 Chemicals
2.2 Methods
2.2.1 Preparations of Reagents
2.2.1.1 Sodium Chloride (Concentration)
2.2.1.2 Alkaline Picric Acid
2.2.1.3 Sulfuric Acid
2.2.1.4 Sodium Hydroxide
2.2.1.5 Sodium Tungstate (Concentration)
2.2.1.6 Creatinine Standard
2.2.2 Urine collection
2.2.3 Determination of height and blood pressure
2.2.4 Determination of Blood pressure
2.2.5 Determination of obesity
2.2.6 Determination of sodium ion concentration in 24 hour urine
2.2.7 Determination of sodium ion concentration in spot urine
2.2.8 Determination of 24 hour creatinine concentration
2.2.9 Determination of creatinine concentration in spot urine
2.2.10 Statistical analysis
CHAPTER THREE: RESULTS
3.1 Baseline characteristics of subjects in measured 24 hour
urinary excretion of sodium by sex aged 20-50 years
3.2 Characteristics of subjects in estimated 24 hour
urinary sodium excretion by sex aged 20-50 years
3.3 Relationship between measured and estimated
24 hour urinary sodium excretion (T-Test)
3.4 Group characteristics of subjects
in measured and estimated 24hour urinary sodium excretion
3.5 Mean and correlation coefficient of measured and estimated
24 hour urinary sodium of subjects aged 20-50 years
3.6 Relationship between systolic blood pressure and
24 hour urinary sodium excretion
3.7 Relationship between diastolic blood pressure and 24 hour sodium excretion
3.8 Relationship between measured 24 hour urinary sodium
excretion and estimated 24 hour urinary sodium excretion
3.9 Measured and estimated 24 hour urinary sodium excretion
of subjects with varying age ranges
3.10 Variation of salt (NaCl) excretion with age ranges
CHAPTER FOUR: DISCUSSION
4.1 Discussion
4.2 Conclusion
4.3 Suggestion for further studies
REFERENCES
APPENDICES
CHAPTER ONE
INTRODUCTION
Sodium chloride (NaCl) is a prototypical stimulant that elicits salty taste. Sodium chloride is a commonly used food ingredient which provides many technological functions such as Flavor enhancement, preservation and texture modification (Hutton, 2002). Sodium (Na) also performs a number of vital roles in the body including maintaining the volume of extracellular fluid, osmotic pressure, acid-base balance and transmission of nerves impulses (Geerling and Loewy, 2008).
Unlike other essential minerals such as calcium, we do not have large stores of sodium in the body and need to constantly replenish sodium via the diet (Reddy and Marth, 1991). While sodium is essential for normal human body functioning, current sodium intakes far exceed recommendation for good health (Brown and Tzoulaki, 2009). This is a problem because there is a strong positive relationship between sodium intake and raised blood pressure.
Raised blood pressure is a major cause of cardiovascular diseases, responsible for 62% of stroke and 49% of coronary heart disease (He and MacGregor, 2010). Excess sodium consumption has also been linked to numerous other negative health effects including gastric cancer (Tsugane et al., 2004), decreased bone mineral density (Devine et al., 2000) and obesity (He et al., 2008).
In general attempts to reduce dietary sodium intake through sodium restricted diets have shown short term success but have lacked long term sustainability and practicality for large populations due to high level of sodium in processed foods and the significant contribution of processed foods to our diet (James et al., 1987). Also, a reduction of sodium chloride in foods is accompanied by a loss of palatability of those foods (Mattes, 2007). The ideal solution would be to reduce the concentration of sodium in the food while retaining optimum saltiness for palatability. One strategy to reduce sodium is to replace with potassium salts, and while potassium chloride elicits weak saltiness at higher concentrations it also elicits metallic and bitter taste limiting its utility in foods (Ainsworth and Plunkett, 2007).
However, minimizing those ‘off-flavors’ means potassium could be an effective salt taste replacer. Arguably, the human diet has undergone more significant changes in the past 50 years than in the past 10 million years (Cordian et al., 2005). One of such modification is the molar ratio consumption of sodium to potassium. Historically, hominid diet contains high potassium and low sodium concentration due to a diet consisting largely of fruit, vegetables and whole grains (Cordian et al., 2005). Our evolutionary forbears had a need to consume sodium, and the sodium was a scarce dietary element, we developed an appetitive response to sodium via salt taste (Mela, 2006). Although the taste mechanism for sodium has not changed, the food supply has developed to suit our appetitive desire and the modern western diet contains a high proportion of processed food with high levels of sodium, which is inherently appealing to humans (Mattes, 2001).
Moreover, fruit and vegetables are the major source of dietary potassium but they are not much consumed in the diet. High consumption of processed food has resulted in a decrease intake of potassium and increase intake of sodium which has much negative health effect including raise blood pressure, obesity and decreased mineral density etc. In recognition of the risks posed by the excessive consumption of sodium, a new daily consumption limit of less than 5g/day...
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