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Assessing the effectiveness of a DASH diet in hypertensive patients attending the Ngaoundere Regional Hospital – Cameroon: a case–control study

Published online by Cambridge University Press:  25 July 2023

Mireille Flore D. Kenmoue ,
Wilfred D. Ngaha ,
Edith N. Fombang ,
Majeste M. Pahane  and
Stephane Simeu
Mireille Flore D. Kenmoue
Affiliation:
Department of Food Sciences and Nutrition, National School of Agro-Industrial Sciences, The University of Ngaoundere, P.O. BOX 455, Ngaoundere, Cameroon
Wilfred D. Ngaha*
Affiliation:
Department of Food Sciences and Nutrition, National School of Agro-Industrial Sciences, The University of Ngaoundere, P.O. BOX 455, Ngaoundere, Cameroon
Edith N. Fombang
Affiliation:
Department of Food Sciences and Nutrition, National School of Agro-Industrial Sciences, The University of Ngaoundere, P.O. BOX 455, Ngaoundere, Cameroon
Majeste M. Pahane
Affiliation:
Department of Processing and Quality Control, Institute of Fisheries and Aquatic Sciences, The University of Douala, P.O. BOX 7236, Douala-Bassa, Douala, Cameroon
Stephane Simeu
Affiliation:
Service of Cardiology, Regional Hospital of Ngaoundere, P.O. BOX 29 Meiganga, Ngaoundere, Cameroon
*
*Corresponding author: Wilfred D. Ngaha, e-mail ngaha.wilfred@gmail.com

Abstract

Hypertension remains a public health issue in Cameroon, though lifestyle and dietetic measures are the main approaches for the prevention and management of hypertension. The present study aimed at evaluating the impact of a Dietary Approaches to Stop Hypertension (DASH) diet using local foodstuffs on the status of hypertensive patients at the Ngaoundere Regional Hospital. A case–control study was carried out with 160 hypertensive patients divided into two groups, a test and a control group. A food questionnaire was used to evaluate the food habits of patients and design the sheet of the DASH diet to provide a maximum of 2000 kcal/d. The DASH diet was administered to the test group (eighty-eight patients), while the control group (seventy-two patients) consumed their normal diet. Both groups were followed up for 8 weeks. The systolic and diastolic blood pressures (SBP, DBP), body mass index (BMI), triglycerides, HDL-c, LDL-c and total-cholesterol levels of patients of the two groups were measured before and after the intervention. The results indicate that the DASH diet improves all the markers of hypertension in the test group with significant decreases in BMI, SBP, DBP, LDL-c and total-cholesterol. Patients of the control group had fourteen and seven times more risk of having increased systolic and diastolic pressures, respectively, and are thus exposed to hypertension complications. The DASH diet established in this study is therefore effective for the management of hypertension.

Keywords

Blood lipid profileBody mass indexDash dietHypertensionNgaoundere Regional Hospital
Type
Research Article
Information
Journal of Nutritional Science , Volume 12 , 2023 , e84
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Hypertension is a pathologic state characterised by permanent high blood pressure on the walls of vessels, higher than 140 mmHg for systolic blood pressure (SBP) and/or higher than 90 mmHg for diastolic blood pressure (DBP)(1). This high pressure can damage the walls of the blood vessels in the long term. The risk factors of hypertension are mainly associated with food practices and lifestyle, particularly diets rich in salt and fats, alcoholism, tobacco and low or absence of physical exercises, low consumption of fruit and vegetables, aging, family history and overweight(1).

Hypertension affects about a billion people around the world and causes more than 10 million deaths each year, with a prevalence that does not significantly vary between urban (32⋅6 %) and rural (34⋅3 %) areas(1). Women are more affected (37 %) than men (30⋅2 %), and the prevalence increases with age, affecting 19⋅2 % population from 20 to 34 years old, 53⋅8 % of 40–60 years and 72⋅2 % of the population group from 65 years(Reference Houehanou, Amidou and Preux2). Hypertensive patients are exposed to associated pathologies, notably renal and cardiac failures, arterial aneurism, aortic dissection, arrhythmia and cognitive and mental disorder(1). However, a slight reduction in blood pressure could considerably decrease morbidity and mortality related to these related diseases and complications, for example, a decrease of 2 mmHg in the DBP have been reported to reduce by 17 % the prevalence of hypertension, by 6 % the risks of coronary diseases and by 15 % the risks of cerebrovascular accidents(Reference Rossier, Bochud and Devuyst3).

The management of hypertension by medical prescription of antihypertensive treatment and/or by lifestyle-dietetic measures (weight loss, reduction of salt intake, regular physical activity, etc.) aimed at decreasing blood pressure and other risk factors of hypertension like overweight and hyperlipidaemia(Reference Perrine, Lecoffre and Blacher4). Accordingly, the Dietary Approaches to Stop Hypertension (DASH) diet developed in the 1990s in the United States to fight against hypertension, recommends a diet rich in fruits and vegetables, whole cereals, skimmed dairy products, legumes/grains and low in fat, sodium (Na+) and refined sugars, accompanied with regular physical activity(Reference Harnden, Frayn and Hodson5). Several studies have shown the effectiveness of this diet in the management of hypertension, with a significant decrease of the SBP and DBP, weight, waist circumference and serum level of total- and LDL-cholesterol(Reference Yang, Yang and Duan6Reference Lari, Sohouli and Fatahi11), cardiovascular and renal diseases, metabolic syndrome, gestational diabetes and colorectal cancer(Reference Jones-McLean, Hu and Greene-Finestone12).

In Cameroun, more than 25 % of the general population are hypertensive(Reference Mbouemboue and Ngoufack13), and the hypertension management is challenging because of the lack of financial resources, customs, beliefs and the negative perception of the disease(Reference Ewane, Mandengue and Priso14) as well as lack of information/education on the hypertension prevention and management. Some of these constraints can however be circumvented by a DASH diet based on available local resources and taking in account the food habits and practices of the patients. The general objective of the present study was to evaluate the effectiveness of a DASH diet with local foodstuffs in nutritional management of hypertension among patients attending the Ngaoundere Regional Hospital (NRH).

Materials and methods

Sampling

The intervention was a case–control prospective experimental study carried out for eight weeks from December 2021 to February 2022 on hypertensive patients attending the cardiology unit of the NRH. The minimal sample size (N) was calculated using the formula of Lorenz (Eq. 1):

(1)$$N = ( z ) ^2 \times ( p ) ( {1-p} ) /m^2$$

where z is the factor to reach 95 % of interval of confidence (1⋅96); p is the prevalence of hypertension (0⋅25) and m is the margin of error (0⋅05).

The sample size obtained after calculation was 288 subjects. But due to the limited time for the study, a systematic sampling of all the patients having given their consent led to the recruitment of 160 patients, a limitation for this study according to the power sample size. The patients recruited were of both genders and were divided into two groups, a test group of eighty-eight patients following the DASH diet, and a control group of seventy-two patients taking their normal diet with nutritional advices.

Nutritional intervention

Patients were received individually in a consultation room where they could express themselves freely and in all confidence. After obtaining the informed consent, they were subjected to an interview using a questionnaire aimed to collect data on food practices, lifestyle, history of hypertension, but also socio-demographic characteristics like age, gender, marital status, level of education and profession. The data on the food practices was precisely related to food regularly consumed, daily food frequency, food cooking mode, place of consumption of meals (family, restaurant, fast food), and daily frequency and quantity of water consumed. Concerning lifestyle, information on alcohol consumption, smoking tobacco and the practice of physical activity (type and frequency) were investigated.

The patients then received nutritional advice, with those of the test group additionally receiving a 7-d diet plan, established based on the season's foodstuffs available, and partitioned into breakfast (7–9 a.m.), lunch (12–2 p.m.) and dinner (5–7 p.m.). An appointment for follow-up was set at 2 weeks’ interval, but also aiming to evaluate the diet prescribed and make some adjustments where necessary.

Nutritional management

The intervention consisted in administering to the test group, for 8 weeks, a DASH diet (Appendix 1) built up using the results of survey on their food habits and to be followed-up at home, coupled with the practice of a moderate physical activities (walking, bicycle or pastoral work) at least 30 min per day at least three times per week. This DASH diet was rich in fruits, vegetables, skimmed or partially skimmed dairy products, dietary fibres, potassium, calcium and magnesium, moderate in fish, lean meat and poultry, leguminous plants, seeds and dry fruits with hulls, and low in total fat, saturated fatty acids and cholesterol.

The daily total energy intake (DTEI) was estimated based on recommendations of a DASH diet, 2000 kcal divided in three meals and two snacks between the meals. The portions of meals were estimated using food composition tables. Lipid intake accounted for 27 % of the DTEI, cooking oil recommended was soybean oil. Carbohydrate and protein intake were respectively 55 and 18 % of the DTEI. It was recommended to the patients to consume about 2⋅3 g (a teaspoon) of salt (sodium chloride) per day, avoiding monosodium glutamate in their meals, to use not more than six tablespoons of oil in the meals, which should be added at the end of cooking, avoid adding salt to already cooked dishes and to use flavour alternatives like aromatic herbs and spices, and also to consume 2⋅5 to 3 l of water per day. Alcohol intake was limited to a half glass of red wine per day.

Concerning the qualitative aspect, this diet considered the geographic context by preferring foodstuffs resulting from local agriculture. The consumption of fruits and vegetables locally available during the season was strongly recommended (moringa leaves (Moringa oleifera), zom/njapche/koumbi leaves (Solanum nigrum), kenen kenen leaves (Corchorus olitorus), water melon, orange, apple, banana, tangerine, carrot, French beans, cucumbers, okra, etc.). Since the dietary intakes of the patients of the control group were not followed-up and assessed, their energy intake was not estimated.

Nutritional assessment

The assessment of the impact of nutritional intervention was done by measuring SBP and DBP, calculating the body mass index (BMI) (kg/m2) (Eq. 2), and determining the lipid profile (triglycerides, total-cholesterol, LDL-c and HDL-c) of patients at the beginning and at the end of the 8 weeks of experimentation. BMI used to evaluate the risk of health-related problems associated with overweight and obesity was obtained from the weight (kg) of the patient measured using a balance with impedance-meter (Kenlee) of a capacity of 160 kg with a precision of 0⋅1 kg, and height (m) using a UNICEF removable height gauge of a range of 2⋅20 m with a precision of 0⋅01 m.

(2)$${\rm BMI} = \displaystyle{{{\rm Weight}} \over {{\rm Height}^2}}$$

Nutritional status corresponding to BMI values (kg/m2) was ranged as follows: <18⋅5: Underweight; 18⋅5–24⋅9: Normal; 25–29⋅9: Overweight; 30–34⋅9: Primary obesity; 35–39⋅9: Secondary obesity; ≥40: Tertiary Obesity (morbid).

SBP and DBP (mmHg) were measured using an electronic blood pressure monitor (OMRON M6 Confort [HEM-7321-E]). The measurements were done three times with an interval of 1 min between two measurements on sitting patients, at rest and not stressed, the armband of the monitor being placed at the level of the non-dominant arm (left arm for the right-handed and right arm for the left-handed persons). Concerning lipid parameters, blood sample was collected by a nurse, labelled and conveyed to the laboratory of Biomedical Analysis of the NRH for the analysis of serum triglycerides, total, HDL-c and LDL-c levels.

Statistical analysis

The survey sheet was designed using the software Sphinx Plus² – Edition Lexica-V5, and the data analysed using SPSS-v20 software. The qualitative variables were expressed in absolute and relative frequency while the quantitative variables were expressed as mean ± standard deviation for the data with a normal distribution, or as medians with the interquartile intervals for the data not having a normal distribution. The impact of the intervention was evaluated by the test Chi-square test of Mann–Whitney on two series of paired qualitative data. The threshold of signification was fixed at α = 0⋅05.

Ethical considerations

This study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human subjects were approved by the Direction of Regional Hospital of Ngaoundere by delivering an authorisation of research. Appropriate protocols for protecting the rights and privacy of all the participants were applied during the nutritional intervention. Verbal informed consent was obtained from all subjects. Verbal consent was controlled and formally recorded. The agreement clearly stated that participation is not compulsory, participants are free to withdraw from the study at any time or step, and full disclosure of study requirements and risks of the study. The anonymity of the participants was guaranteed, as well as the confidentiality of data collected. In addition, this study did not harm the physical integrity of the patients and did not interfere with their clinical follow-up.

Results and discussion

Socio-demographic characteristics of the study population

The socio-demographic characteristics of the patients are presented in Table 1, with a predominance of men (51⋅2 %) compared to women (48⋅8 %), and this can be due to the fact that android obesity localised in the upper part (abdomen) of the body is most frequent in men is a risk factor of hypertension(Reference Houehanou, Amidou and Preux2). A study carried out in the town of Ngaoundere in 2020 also revealed a high predominance of men (63⋅8 %) among the hypertensive patients(Reference Pancha MO and Nguimbou15).

Table 1. Socio-demographic characteristic of studied patients

The patients were mainly married (70⋅6 %) (Table 1), which is in line with the advanced age of many of them, as 92⋅5 % of the participants were 40 years old and more. Even though an advanced age is a risk factor of hypertension related to the ageing of the blood vessels, results show that patients of 40–59 years (56⋅3 %) represented the higher proportion of the studied population than those from 60 years and above (36⋅2 %). Thus, this can be justified by another risk factor of hypertension associated with age, poor stress management(Reference Ngombe, Cowgill and Monga16). Indeed, contrary to patients 60 years old who are pensioners for the majority, those aged 40–59 years are still active, and thus undergo the pressure and the stress related to the long working days. A study carried out in the Garoua town in Cameroon established that the age group of 46–65 years were the majority in population of hypertensive patients(Reference Mbouemboue, Tamanji and Gambara17). From Table 1, 40 % of patients were unemployed and 11⋅3 % were pensioners, 48⋅7 % of the participants had a job, justifying once more that the stress related to the working days could be a risk factor of hypertension. For the pensioners’ patients, hypertension could be associated with their age with shrinkage and stiffness of their blood vessels.

Concerning the level of education, 32 % of the patients had never gone to formal school or follow certifying education and 313 % have primary school level. Level of education is a significant factor in the development of nutritional intervention programs. Because of their low level of education, about two-third of participants can neither speak, read nor write English and/or French, the two official languages in Cameroon. They are consequently unable to understand the messages and sensitising in the media on hypertension. Moreover, they do not measure the importance of nutrition in their lifestyle. In fact, it was shown that people who received a minimum of education are generally more advised than those who did not, and lack of education can negatively affect the decisions about food choices(Reference Girma and Genebo18). In fact, the higher the level education, the lower is the prevalence of malnutrition among women and their families(Reference Teller and Yimer19).

Physical activity and hypertension antecedents of the participants

The type, frequency and duration of physical activity by the participants, as well as the history of their hypertension are presented in Table 2. Most of the patients (67⋅5 %) did not practice any physical activity before the study, and only 15 % practised more than three times per week, which exposes them to the disease as physical inactivity is one of the risk factors of hypertension(Reference Sosner, Gremeaux and Bosquet20,Reference Masson, Pouponneau and Gaillard21) . Moreover, 61⋅3 % of patients had family history of hypertension (Table 2), one of the causes of occurrence of hypertension(1). About half of the patients (41⋅9 %) were diagnosed less than one year back, while 34⋅4 % of patients were diagnosed more than 5 years back showing that hypertension is diagnosed late in the town of Ngaoundere, which can be related to the lack of information of the patients on the symptoms of the disease, their low level of education, but especially the low rate of hospitals visits by the population.

Table 2. Physical activity, family history and period of diagnosis of hypertension

Lifestyle-dietary practices of surveyed patients

Results on food practices and lifestyle of the patients (Table 3) indicate more than one-third of the patient consume salt in higher quantities for their pathologic state, with only 5 % of the patients consuming three fruits and vegetables per day and 5 % using olive oil to prepare their meals. A total of 85 % of patients use palm oil, refined or not, because of its availability and its accessibility in the markets, though it contains significant proportions of saturated fatty acids(Reference Koushki, Nahidi and Cheraghali22). Indeed, it is recommended to hypertensive patients to significantly reduce their intake of table salt, as there is a high correlation between a diet rich in Na+ and the occurrence of hypertension(Reference Abbes23). Moreover, with their high content in vitamins, minerals, antioxidants and others bioactive compounds, fruits and vegetables are strongly recommended in the management of hypertension, and it is the same for olive oil with its wealth in polyunsaturated fatty acids(Reference Saillard24).

Table 3. Lifestyle-dietary practices of the participants

Cattle breeding is the major activity in the study area, then beef meat is available in the local markets, which explains why 71⋅2 % of the patients consume meat at least three times per week, contrary to fish which is a little bit scarce, and thus less consumed with only 32⋅5 % of participants who eat fish at least three times per week. This result suggests that the feeding habits of the patients are likely to expose them to complications, because red meats must be reduced in the diets for chronic diseases in general and DASH diet. Moreover, fish, in addition, is also a source of unsaturated fatty acids which have properties proven in the management of hypertension(Reference Gosse and Bely25).

Among the patients, 42⋅5 % consumed whole cereals. Cereals are famous for their high content in dietary fibres which are implicated through several mechanisms in the reduction of blood cholesterol and sugar in the body.

Concerning the lifestyle, 70⋅6 % of patients did not consume alcohol and 93⋅7 % of patients did not consume tobacco. However, 13⋅7 % of the patients frequently consumed alcohol and 5 % consumed tobacco. Even though smoking and consumption of alcohol are high risk factors of hypertension(Reference Singh, Dubey and Singh26,Reference Yadav, Allarakha and Shekhar27) , they present a low risk for the patients attending NRH nutrition unit.

Impact of the DASH diet on nutritional status of patients

BMI of patients at the beginning and at the end of the intervention were calculated and the results compiled in Table 4 indicate that the DASH diet has improved the nutritional status of patients of test group by significantly reducing their BMI. Indeed, the percentage of patients suffering from obesity dropped from 47⋅7 % before intervention to 22⋅7 % after intervention, corresponding to a global drop of about 43 % of obese patients. Furthermore, there was an increase in the proportion of the patients having a normal BMI from 18⋅2 to 36⋅4 %, corresponding to a global increase of 50 % of patients of the normal weight. This can be explained by the limited amount of energy supplied (2000 kcal/d) by the dash diet used. This DASH diet is also rich in fruit and vegetables containing antioxidants that may influence fat metabolism(Reference Van der Werf28), and also rich in whole cereals containing dietary fibres implicated in the reduction of blood glucose and lipid levels, thus limiting their storage in the form of energy(Reference Mohamed29). This diet combined with the practice of physical activity, largely contributed to the reduction of body weight of the patients, as reported in a similar study carried out in Algeria(Reference Abbes23).

Table 4. Effect of the diet on the body mass index of patients

Test group n 88; Control group n 72.

Bold values indicate that the difference is statistically significant (P-value < 0.05).

Impact of DASH diet of blood pressure of the patients

SBP and DBP of the patients before and after the intervention are presented in Table 5. There is a significant decrease (P < 0⋅05) in the SBP and DBP in both test and control groups. This reduction is of about 28 and 18 mmHg, respectively, for SBP and DBP in the test group, 27 and 15 mmHg in the control group and can be explained by the fact that all the patients in the test and control groups, were under antihypertensive treatment during the period of the study, which would have contributed to this significant decrease in blood pressure. However, a comparison of the average values of the variations of DBP (Fig. 1) shows a higher decrease in the test (P < 0⋅05) compare to the control group. This could be justified by the benefits of the experimental diet, in particular the reduction of Na+ intake and the consumption of fruits, vegetables and fish(Reference Abbes23). The regular consumption of fish which is rich in ω-3 polyunsaturated fatty acids (3 times per week) and vegetable oils rich in unsaturated fatty acids leads to the decrease in the blood pressure, and can be recommended among hypertensive patients(Reference Gosse and Bely25).

Table 5. Systolic and diastolic blood pressures before and after the diet

SBP, systolic blood pressure; DBP, diastolic blood pressure.

Bold values indicate that the difference is statistically significant (P-value < 0.05).

Fig. 1. Comparison of diastolic blood pressure variations between case and control groups.

DASH diet and severity of systolic and diastolic blood pressures

The impact of the DASH diet on the evolution of the severity of hypertension is presented in Table 6. For the SBP, there is a significant improvement (P < 0⋅05) in the test group, with the prevalence of the patients at the advanced stages (grades 1, 2 and 3) passing from 88⋅7 % at the beginning of the study to 4⋅5 %, with no patient at the grades 2 and 3 at the end of the study. The same trend was observed for the DBP with the proportion of patients with advanced stage of the disease passing from 84 to 9 %, without patient in grade 3 at the end of the study. These results confirm once more the effectiveness of this DASH diet in the management of hypertension.

Table 6. Effect of diet on the severity of systolic and diastolic blood pressures

a Normal high/Test group n 88; Control group n 72.

Bold values indicate that the difference is statistically significant (P-value < 0.05).

The decrease in blood pressure observed in this study may also be due to the richness of the elaborated DASH diet in calcium (Ca2+), magnesium (Mg2+) and potassium (K+) which are vasodilator minerals. Indeed, the movement of Ca2+ on both sides of the cellular membrane is accompanied by a reduction of the blood pressure and a decrease in the intracellular concentration of Ca2+, causing a relaxation of vascular fibres and thus a vasodilatation(Reference Carbone, Bush and Barrow30). Mg2+, on the other hand, acts on vascular tonicity through mediators like nitric oxide (NO), endotheline-1 and the derivatives of prostaglandins released by the endothelium and lowers the blood pressure(Reference Yang, Gebrewold and Nowakowski31). For the case of K+, it reduces the blood pressure by acting on the urinary elimination of Na+ and water(Reference Akita, Sacks and Svetkey32). K+ would have also the capacity to recover noradrenalin at the level of nervous terminations and consequently is effective as a vasodilator leading to a reduction of the blood pressure(Reference Gallen, Rosa and Esparaz33).

Effect of DASH diet on the lipid profile of the patients

Lipid profile of the patients before and after the study is presented in Table 7. Except triglyceride concentration, DASH diet has a significant impact (P < 0⋅05) on the lipid parameters. Total-cholesterol and LDL-c levels decrease for the patients of the test group based on average by 10⋅86 and 9⋅56 mg/dl, respectively, while their HDL-c level increased by 4⋅34 mg/dl. Total-cholesterol level significantly (P < 0⋅05) decreases in the test group than the control group (Fig. 2). These results highlight the effectiveness of the established DASH diet using local foodstuffs from Ngaoundere in the management of hypertension and its risk factors. Indeed, this drop in total- and LDL-cholesterol accompanied by an increase in the rate of HDL-cholesterol is the result of a diet rich in dietary fibres, antioxidants and unsaturated fatty acids from foodstuffs selected.

Table 7. Lipid profile of patients before and after the intervention

Bold values indicate that the difference is statistically significant (P-value < 0.05).

Fig. 2. Comparison of variation of total-cholesterol level between case and control groups.

Risk of exposure of patients

Level of risk of exposure to hypertension (increasing in SBP and DBP) according to the observance of DASH diet among patients is presented in Table 8. Compared to the patients of the test group who received DASH diet, the patients of the control group had fourteen times more risk of increasing the SBP and seven times more risk for the DBP, which also increases the risk of complications. In fact, the DASH diet is high in antioxidants contained in fruits, vegetables and whole grains, and this diet raised antioxidant capacity compared with that of usual diets. The DASH diet may lower BP by raising antioxidant capacity and improving the balance between antioxidant defences and oxidative stress. A study has besides reported that antioxidant capacity, measured by the FRAP assay, was higher in lean normotensives than in obese hypertensives on their usual diets(Reference Lopes, Martin and Nashar34).

Table 8. Relative risk of hypertension in the participants

Conclusion

The good application of a DASH diet established from available food resources in the town of Ngaoundere contributes effectively to the management of hypertension, by improving the physiological (SBP and DBP), anthropometric (BMI) and lipid (total-, HDL- and LDL-cholesterol) parameters of the hypertensive patients. The application of DASH diet proposed reduces the risk of complications mainly by fourteen times the risk links to an increasing of the SBP and by seven times the risk links to an increasing of the DBP.

Acknowledgements

The authors are grateful to the patients who participated to the study, giving free their time for the preferment of science. We also thank Marilyn Nanyongo Vagwah, Nutritionist at the General Hospital of Douala-Cameroon for reading and reviewing the first draft of this article, and Guy Christian Fomekong, PhD student in the Department of Food Science and Nutrition of the National School of Agro-Industrial Sciences, for statistical analysis.

No funding was received for this study.

Conceptualisation, E. N. F. and W. D. N.; Methodology and work on the field, M. F. D. K. and S. S.; Formal analysis, M. F. D. K. and W. D. N.; Writing – original draft, M. F. D. K. and M. M. P.; Writing – review and editing, W. D. N. and E. N. F.

The authors declare no conflict of interest.

Appendix 1: Seven-day diet plan for the test group

Footnotes

tbsp., tablespoon; Kenen kenen, Corchorus olitorus; Zom, Solanum nigrum.

References

OMS (2013) Panorama mondial de l'hypertension: un tueur silencieux responsable d'une crise de santé publique mondiale: Journée mondiale de la santé 2013. WHO/DCO/WHD/2013.2, 40p. Organisation mondiale de la Santé.Google Scholar
Houehanou, C, Amidou, S, Preux, P-M, et al. (2018) Hypertension artérielle (HTA) en Afrique subsaharienne. J Méd Vasc 43, 87.Google Scholar
Rossier, BC, Bochud, M & Devuyst, O (2017) The hypertension pandemic: an evolutionary perspective. Physiology 32, 112125.CrossRefGoogle ScholarPubMed
Perrine, A, Lecoffre, C, Blacher, J, et al. (2019) L'hypertension artérielle en France: prévalence, traitement et contrôle en 2015 et évolutions depuis 2006. Rev Biol Méd 347, 7585.Google Scholar
Harnden, K, Frayn, K & Hodson, L (2010) Dietary Approaches to Stop Hypertension (DASH) diet: applicability and acceptability to a UK population. J Hum Nutr Diet 23, 310.CrossRefGoogle ScholarPubMed
Yang, Z-Q, Yang, Z & Duan, M-L (2019) Dietary Approach to Stop Hypertension diet and risk of coronary artery disease: a meta-analysis of prospective cohort studies. Int J Food Sci Nutr 70, 668674.CrossRefGoogle ScholarPubMed
Juraschek, SP, Miller, ER, Weaver, CM, et al. (2017) Effects of sodium reduction and the DASH diet in relation to baseline blood pressure. J Am Coll Cardiol 70, 28412848.CrossRefGoogle ScholarPubMed
Rai, SK, Fung, TT, Lu, N, et al. (2017) The Dietary Approaches to Stop Hypertension (DASH) diet, western diet, and risk of gout in men: prospective cohort study. Br Med J 357, 18.Google ScholarPubMed
Sacks, FM, Svetkey, LP, Vollmer, WM, et al. (2001) Effects on blood pressure of reduced dietary sodium and the Dietary Approaches to Stop Hypertension (DASH) diet. N Engl J Med 344, 310.CrossRefGoogle ScholarPubMed
Chiu, S, Bergeron, N, Williams, PT, et al. (2016) Comparison of the DASH (Dietary Approaches to Stop Hypertension) diet and a higher-fat DASH diet on blood pressure and lipids and lipoproteins: a randomized controlled trial–3. Am J Clin Nutr 103, 341347.CrossRefGoogle Scholar
Lari, A, Sohouli, MH, Fatahi, S, et al. (2021) The effects of the Dietary Approaches to Stop Hypertension (DASH) diet on metabolic risk factors in patients with chronic disease: a systematic review and meta-analysis of randomized controlled trials. Nutr Metab Cardiovasc Dis 31, 27662778.CrossRefGoogle ScholarPubMed
Jones-McLean, E, Hu, J, Greene-Finestone, L, et al. (2015) Régime DASH et risque de cancer colorectal chez les adultes canadiens. Promotion de la sante et prévention des maladies chroniques au Canada 35, 1424.CrossRefGoogle Scholar
Mbouemboue, OP & Ngoufack, TJO (2019) High blood pressure prevalence, awareness, control, and associated factors in a low-resource African setting. Front Cardiovasc Med 6, 119.CrossRefGoogle Scholar
Ewane, ME, Mandengue, SH, Priso, EB, et al. (2012) Dépistage des maladies cardiovasculaires chez des étudiants de l'Université de Douala et influence des activités physiques et sportives. Pan Afr Med J, 11, 116.Google Scholar
Pancha MO, TJON & Nguimbou, RM (2020) Effets à Court Terme d'un Régime DASH sur les Profils Cliniques et Anthropométriques d'un Groupe d'Hypertendus. Health Sci Dis 21, 3942.Google Scholar
Ngombe, LK, Cowgill, K, Monga, BB, et al. (2015) Prévalence de l'hypertension artérielle dans la population des meuniers de la ville de Lubumbashi, République Démocratique du Congo. Pan Afr Med J 22, 112.CrossRefGoogle Scholar
Mbouemboue, OP, Tamanji, MT, Gambara, R, et al. (2016) Determinants of therapeutic nonadherence to antihypertensive treatment: a hospital-based study on outpatients in northern Cameroon. Int J Med Sci Public Health 5, 1.CrossRefGoogle Scholar
Girma, W & Genebo, T (2002) Determinants of nutritional status of women and children in Ethiopia.Google Scholar
Teller, CH & Yimer, G (2000) Levels and determinants of malnutrition in adolescent and adult women in southern Ethiopia. Ethiop J Health Dev 14, 5766.Google Scholar
Sosner, P, Gremeaux, V, Bosquet, L, et al. (2014) Hypertension artérielle et exercice physique–Mise au point pratique. In Annales de Cardiologie et d'Angéiologie, 63:3, 197203. Paris: Elsevier Masson.Google Scholar
Masson, F, Pouponneau, A, Gaillard, T, et al. (2021) L'activité physique au service de la prévention cardio-vasculaire. Actual Pharm 60, 3438.Google Scholar
Koushki, M, Nahidi, M, Cheraghali, F, et al. (2015) Physico-chemical properties, fatty acid profile and nutrition in palm oil. Arch Adv Biosci 6, 117134.Google Scholar
Abbes, MA (2017) Etude de l'impact du poids corporel sur l'hypertension artérielle cas des hypertendus de Tiaret. Thèse de Doctorat.Google Scholar
Saillard, MJO (2014) Les effets « santé » de l'huile d'olive. 21, D510.Google Scholar
Gosse, P & Bely, H (2004) Prescription diététique dans l'hypertension artérielle. EMC-Médecine 1, 3741.CrossRefGoogle Scholar
Singh, PK, Dubey, R, Singh, L, et al. (2022) Mixed effect of alcohol, smoking, and smokeless tobacco use on hypertension among adult population in India: a nationally representative cross-sectional study. Int J Environ Res Public Health 19, 3239.CrossRefGoogle ScholarPubMed
Yadav, J, Allarakha, S, Shekhar, C, et al. (2021) Health G: Alcohol and tobacco influencing prevalence of hypertension among 15–54 years old Indian men: an application of discriminant analysis using National Family Health Survey (NFHS), 2015–16. Clin Epidemiol Global Health 12, 100894.CrossRefGoogle Scholar
Van der Werf, R (2013) Evaluation du pouvoir anti-oxydant des aliments : Recherche de leurs effets modulateurs sur le stress oxydant dans le cas du diabète. Strasbourg, France: Université de Strasbourg.Google Scholar
Mohamed, AB (2018) Impact des fibres alimentaires et des acides gras à chaîne courte sur le dialogue tube digestif, foie et tissus périphériques, dans le cadre d'une surnutrition. Clermont, France: Université Clermont Auvergne.Google Scholar
Carbone, LD, Bush, AJ, Barrow, KD, et al. (2003) The relationship of sodium intake to calcium and sodium excretion and bone mineral density of the hip in postmenopausal African American and Caucasian women. J Bone Metab 21, 415420.CrossRefGoogle ScholarPubMed
Yang, ZW, Gebrewold, A, Nowakowski, M, et al. (2000) Mg2+-induced endothelium-dependent relaxation of blood vessels and blood pressure lowering: role of NO. Am J Physiol-Regul Integr Comp Physiol 278, R628R639.CrossRefGoogle Scholar
Akita, S, Sacks, FM, Svetkey, LP, et al. (2003) Effects of the Dietary Approaches to Stop Hypertension (DASH) diet on the pressure-natriuresis relationship. Hypertension 42, 813.CrossRefGoogle ScholarPubMed
Gallen, IW, Rosa, RM, Esparaz, DY, et al. (1998) On the mechanism of the effects of potassium restriction on blood pressure and renal sodium retention. Am J Kidney Dis 31, 1927.CrossRefGoogle ScholarPubMed
Lopes, HF, Martin, KL, Nashar, K, et al. (2003) DASH diet lowers blood pressure and lipid-induced oxidative stress in obesity. Hypertension 41, 422430.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Socio-demographic characteristic of studied patients

Figure 1

Table 2. Physical activity, family history and period of diagnosis of hypertension

Figure 2

Table 3. Lifestyle-dietary practices of the participants

Figure 3

Table 4. Effect of the diet on the body mass index of patients

Figure 4

Table 5. Systolic and diastolic blood pressures before and after the diet

Figure 5

Fig. 1. Comparison of diastolic blood pressure variations between case and control groups.

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Table 6. Effect of diet on the severity of systolic and diastolic blood pressures

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Table 7. Lipid profile of patients before and after the intervention

Figure 8

Fig. 2. Comparison of variation of total-cholesterol level between case and control groups.

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Table 8. Relative risk of hypertension in the participants