Medicinal & Aromatic Plants
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Treatment of Diabetes and/or Hypertension Using Medicinal Plants in Cameroon

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Introduction

Hypertension affects approximately 70% of patients with type 2 diabetes, 30% of patients with type 1 diabetes and it is approximately twice as common in persons with diabetes as in non-diabetics [1]. The prevalence of coexistent hypertension and diabetes substantially varies across different socio-cultural and racial groups. The overlap between hypertension and diabetes provokes the risk of vascular complications in the population, and together both pathologies predispose to chronic nephropathy, retinopathy and sexual dysfunction [2]. Diabetes mellitus is an independent risk factor for coronary artery disease, and the risk is markedly increased when hypertension is present. The incidence and prevalence of type 2 diabetes are increasing [3,4]. According to Bild and Teutsch [5], the total number of people with diabetes will rise from 171 million in 2000 to 366 million by 2030. The number of adults with hypertension is predicted to increase by 60% to a total of 1.56 billion people by 2025 [6]. Particularly in Cameroon, epidemiological studies have shown that 10% of the population is diabetics, 90% of them were fat at the beginning of the disease and the prevalence of hypertension adjusted to the age is 16.6% in men and 12.6% in women in urban population. Diabetic nephropathy is the commonest cause of hypertension in patients with type 1 diabetes. Patients with type 2 diabetes can develop renal disease, but hypertension commonly occurs without abnormal renal function and is often associated with central obesity. Insulin resistance and diabetes can precipitate hypertension by stimulating the sympathetic nervous system and the renin–angiotensin system, and promoting sodium retention. Diabetes is also associated with increased proliferation of vascular smooth muscle cells. High blood glucose and elevated blood pressure can impair vascular endothelial cells, leading to increased oxidative stress. Patients with diabetes also have increased vascular reactivity. Then there is a real need to prevent or to treat quickly both diseases. Herbal remedies are commonly used in Cameroon for the treatment of diseases since they are easily accessible and less expensive compared to conventional drugs. So can plants be required in the management of different types of diabetics and hypertensive patients and what is the prominence of each disease in the population? To answer this question, data were collected from 182 patients, previously diagnosed at least once by a physician as diabetics and/or hypertensive patients who use familiar herbal remedies.

Methodology

Patients’ criteria selection

Patients admitted in this study have presented a medical book or a bulletin of medical exam that certifies their diabetic and/or hypertensive state at the moment of their selection. During the clinical following up, they have used the familiar blood pressure monitor and/or the familiar glycemic monitor to control daily blood pressure or fasting blood sugar concentration

Participants

To reach our objective, we selected for this study 182 patients upon 328 who have been diagnosed at least once in medical centers and who took different varieties of herbal remedies and accept the clinical following up for a period of 10 days. They were distributed in three groups: confirmed diabetics, confirmed hypertensive patients and confirmed diabetics with hypertension patients.

Research of minimal efficient therapeutic dosage of each plant used by followed up patients and minimal duration of treatment

Only the more efficient dosage for a given plant prepared with a minimal quantity of plant material for a minimal time of treatment was selected. The daily fasten glycemic and/or the blood pressure of each patient in treatment were measured until the normal fasting glycaemia (0.66 to 1.1 g/l) or the normal blood pressure (110 to 130 mmhg for systolic and 70 to 90 mmhg for diastolic).

Data were collected using an ethnobotanical data form and from 182 upon 328 patients drawn in 28 tribes in Cameroon. All plants recorded here were described in detail with the precision of the quantity of plant material, volume of water, time of ebullition, maceration or infusion, quality of preparation used per dosage, the number uses per day and duration of treatment [7].

Results

Clinical following up of diabetes and/or hypertensive patients

One hundred and eighty two (182) confirmed patients (106 diabetics, 66 hypertensive patients and 10 diabetic and hypertensive patients) used familiar herbal remedies. Familiar herbal remedies have regulated the hyperglycemia and/or the high blood pressure for 129 /182 patients (70.87%). Oral use of herbal remedies has relieved the hyperglycemia of 80% of patients of NIDD, of 69.44% of patients of IDD on the one hand, the high blood pressure of 46.15% of patients of essential hypertension and 65.07% of patients of secondary hypertension on the other hand. The analysis of the different glycemic values and blood pressure in Table 1 reveal the 2 following tendencies:

A total of 86 abnormal blood pressure values (53 systolic values ≥140 mmHg + 33 diastolic values ≥90 mmHg) upon 152 have been regulated, representing 56,57%. However 22 of such values have persisted after the treatment, representing 14.47%. At last 33 diastolic normal values (21.71%) remained constant until the end of the treatment. At last a normal systolic value that represents 0.65% remained constant until the end of the treatment. For the two diseases 64.17% of glycemic values and blood pressure values have been regulated.

These increased percentages constitute an element that sustains the use of herbal remedies in the treatment of the two pathologies. However because of the disparity observed in the results of treatment, it is necessary to precise that the use of plants must be done under a control of a physician. Stop the treatment, after a time to determine from that the glycaemia and/or the blood pressure become normal. This precision must avoid the excessive use of herbal remedies and the danger of hypoglycemia and hypotension.

Table 1: Distribution of glycemic and blood pressure values of the followed up patients according to sex.

Plants used by the 182 followed up patients

Thirty-three plants were used by the 182 followed up patients. The minimal efficient dosage of each of these plants was taken in consideration. It is expressed sometimes in function of patients’ weight and is subsequently described in details in Table 2. This table shows the most useful plants in term of the number of patients and/or diseases relieved.

Table 2: Distribution of the followed up patients according to the plants used and their healer condition.

Discussion

The abandon of several foods in benefit of sweet coffee and milk by the urban populations including hypoglycemic garden eggs Solanum melongena in the form of a decoction called ‘medip-me-zon’ in Boulou tribe, the soup with garden eggs of fufu called ‘ashu’ and ‘abalah ‘respectively in North West and West regions and the soup of fufu corn with hypoglycemic Corchorus olitorius called ‘lalo’ in Fulfulbe and Kenekene in Eton and the lack of physical exercises can explain the increase prevalence of the diabetes and hypertension in towns.

The high percentage of regulated or relieved patients (70, 87%) depends on many factors including the aggravation of the diseases by the development of complications, the causes of diseases and the mechanisms of the herbal remedies including insulin-secretion and peripheral action. Most of the unrelieved patients have developed the disease for a long time.

Insulin-secretion

It is the pancreatic action that is possible if β- cells still available (Figure 1). In the Table 2 the plants* endowed of this mechanism of action can treat only the type 2 diabetes. These plants are comparable to oral hypoglycemic products and produce normal diabetic insulin [7]. But their prolonged use provokes the death of β-cells due to functional overwork. Progressively the patient passes from type 2 (NIDD) to type 1 (IDD).

Figure 1: Diabetic; photograph 2 Hypertensive patient: (a) Glycemic monitor; (b) Blood pressure monitor.

Peripheral effect

It is the extrapancreatic action (as injected insulin) (Figure 2). The Table 2 present the plants with this action.

Figure 2: Mechanisms’ comparison action of normal diabetic insulin (left) and injectable insulin (right) (Upjohn).

Insulin-secretion and peripheral effect

The two mechanisms present by the plants* of Table 2.

Essential hypertension

Phyllanthus niruri is an inhibitor of conversion enzyme (ICE). These compounds are hypotensive and they interfere with the liberation of angiotensin. The Heart Outcomes Prevention Evaluation study showed that inhibition of angiotensin-converting enzyme in patients with type 2 diabetes reduces the risk of vascular complications [8]. Therefore this plant can be required in the management of these patients, but lifestyle modification and weight management are key components to reduce glycemia and control blood pressure.

Amaechina and Omogbai [9] reported that intravenous administration of the aqueous extract of the leaves of Phyllanthus amarus (5-80 mg/kg) to anesthetized male rabbits produced a significant fall in mean diastolic, systolic, and mean arterial pressures in a graded dose-response manner. The dose of 5 mg/kg produced the least hypotensive effect, causing a fall in mean diastolic, systolic, and mean arterial pressure of 13.3 ± 3.1, 19.7 ± 5.4, and 14.3 ± 3.4 mmHg, respectively, whereas the dose of 80 mg/kg produced the greatest fall in mean diastolic, systolic, and mean arterial pressure of 49.7 ± 7.9, 45.5 ± 9.5, and 48.00 ± 6.5 mmHg, respectively. The extract produced greater depressant effect on the diastolic blood pressure than the systolic blood pressure.

Secondary hypertension

Some plants 1 in Table 2 low the rate of cholesterol and/or blood triglycerides, responsible of certain secondary or certain hypotensive properties which provoke peripheral vasodilatation hypertensions contain. Therefore they can treat hypertensions due to arteriosclerosis. Rauvolfia vomitoria reacts like a central antihypertensive product; as vasodilator of coronary vessels and as a regulator of cardiac rhythm in patients suffering of tachycardia. Allium cepa is a diuretic; it treats some hypertensive patients by facilitating the blood circulation and prevents thrombosis, responsible of some secondary hypertensions. This favorable effect can be partially explained by the physio-pathological mechanisms conceivable in African population like hypervolemia (strong blood concentration in salt), the sensibility in salt, the excessive consumption of salt and the climate conditions. In anesthetized rats, the crude extract of the leaves of Moringa oleifera caused a fall in systolic, diastolic, and mean blood pressure in a dose-dependent manner. It was also established that thiocarbamate and isothiocyanate fractions of this crude extract were responsible for the antihypertensive activity. Sacks, et al. and Mojiminiyi et al. [10,11] reported the antihypertensive effect of calyx of Hibiscus sabdariffa. The antihypertensive effects of the crude extract have been attributed to mediation through acetylcholine and histamine like dependent mechanism through direct vasorelaxant effects [12]. Earlier report showed that the petal crude extract had a direct relaxant effect on the aortic smooth muscle of rats [13]. The chronic administration of aqueous extract reports to reverse cardiac hypertrophy in renovascular hypertensive rats [14].

Clinical trials of the plant extract in human being show trustworthy evidence of antihypertensive effects. A standardized doses of 9.6 mg per day given to 39 patients, 50 mg per day given to the same number of patients don’t show significant difference relative to hypotensive effects, antihypertensive effectiveness and tolerability [15].

Conclusion

In Cameroon, the persisted economic crisis, the insulin-resistance, the resistance of some hypertensions to antihypertensive products and certain germs to synthetic antibiotics has reinforced the recourse to traditional medicine in both urban and rural populations.

The clinical follow up of diabetics and/or hypertensive patients in treatment with familiar herbal remedies led to the identification of 33 hypoglycemic and/or antihypertensive plants. In general the oral use of these 33 plants have reduced the hyperglycemia of 80% of NID patients, 69.4% of IDD patients on the one hand; the high blood pressure of 46.1% of patients of essential hypertension and 65.1% of patients of secondary hypertension on the other hand. For the two diseases 172 glycemic and tension values upon 268 were regulated representing 64.17% [16]. Some plants including Momordica charantia, Sclerocarya birrea and Ceiba pentandra have revealed two interesting mechanisms of action: pancreatic and extra-pancreatic in the treatment of diabetes. Phyllanthus niruri is an inhibitor action for the production aldosterone responsible of certain severe hypertensions [17].

The knowledge of bioactive plants can contribute to the better treatment of patients and the improvement of the quality of sociosanitary allowance administrated to them [7]. But many other plants need to be investigated. It is also necessary to carry out advanced investigations on the study of different toxicities of the herbal remedies.

Acknowledgements

The authors acknowledge the respondents (traditional healers and diabetic and/or hypertensive patients) and the nurses for their contribution during the ethnobotanical survey.

References

1. Canadian Diabetes Association Clinical Practice Guidelines Expert Committee.  (2008). Canadian Diabetes Association 2008 clinical practice guidelines for the prevention and management of diabetes in Canada. Can J Diab 32: S1-201.
2. Brenner BM, Cooper ME, de Zeeuw D, Keane WF, Mitch WE, et al. (2001) Renal Study Investigators. Effects of losartan on renal and cardiovascular outcomes in patients with type 2 diabetes and nephropathy. N Engl J Med 345:861-9.
3. Public Health Agency of Canada (2009)  Report from the National Diabetes Surveillance System: diabetes in Canada. Ottawa, ON: Public Health Agency of Canada
4. Public Health Agency of Canada (2010)  Report from the Canadian Chronic Disease Surveillance System: hypertension in Canada. Ottawa, ON: Public Health Agency of Canada
5. Bild D, Teutsch SM(1987)The control of hypertension in persons with diabetes: a public health approach. Publ Health Rep102:522-529.
6. Sowers JR, Epstein M, Frohlich ED (2001) Diabetes, hypertension, and cardiovascular disease: an update. Hypertension37:1053-1059.
7. Tsabang N (2008)Ethnobotanical study of plants has antidiabetic properties and / or antihypertensive Cameroon. Thesis / PhD , University of Yaoundé I: 319.
8. Hackam DG, Khan NA, Hemmelgarn BR, Rabkin SW, Touyz RM, et al. (2010) Canadian Hypertension Education Program The 2010 Canadian Hypertension Education Program recommendations for the management of hypertension: part 2—therapy. Can J Cardiol 26:249-258.
9. Amaechina FC, Omogbai EK (2007) Hypotensive effect of aqueous extract of the leaves of Phyllanthus amarus Schum and Thonn (Euphorbiaceae) Acta Pol Pharm 64:547-52.
10. Sacks FM, Lichtenstein A, Van Horn L, Harris W, Kris-Etherton P, et al.(2006) Soy protein, isoflavones, and cardiovascular health: A summary of a statement for professionals from the american heart association nutrition committee. Arterioscler Thromb Vasc Biol 26:1689-92.
11. Mojiminiyi FB, Dikko M, Muhammad BY, Ojobor PD, Ajagbonna OP, et al.(2007) Antihypertensive effect of an aqueous extract of the calyx of Hibiscus sabdariffa. Fitoterapia 78:292-297.
12. Adegunloye BJ, Omoniyi JO, Owolabi OA, Ajagbonna OP, Sofola OA, et al.(1996) Mechanisms of the blood pressure lowering effect of the calyx extract of Hibiscus sabdariffa in rats. Afr J Med Sci 25:235-238.
13. Sarr M, Ngom S, Kane MO, Wele A, Diop D, et al. (2009) In vitro vasorelaxation mechanisms of bioactive compounds extracted from Hibiscus sabdariffa on rat thoracic aorta. Nutr Metab 6:45.
14. Odigie IP, Ettarh RR, Adigun SA (2003) Chronic administration of aqueous extract of Hibiscus sabdariffa attenuates hypertension and reverses cardiac hypertrophy in 2K-1C hypertensive rats. J Ethnopharmacol 86:181-5.
15. Herrera-Arellano A, Flores-Romero S, Chávez-Soto MA, Tortoriello J (2004) Effectiveness and tolerability of a standardized extract from Hibiscus sabdariffa in patients with mild to moderate hypertension: A controlled and randomized clinical trial. Phytomedicine 11: 375-382.
16. Barnett AH (1994) Diabetes and hypertension University of Birmingham, Birmingham Heartlands Hospital Birmingham, UK. Br Med Bull 50: 397-407.
17. Sowers JR, Epstein M, Frohlich ED (2001) Diabetes, hypertension, and cardiovascular disease: an update. Hypertension37:1053-1059.