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African Health Sciences logoLink to African Health Sciences
. 2013 Sep;13(3):546–550. doi: 10.4314/ahs.v13i3.2

Overnight soaking or boiling of “Matooke” to reduce potassium content for patients with chronic kidney disease: does it really work?

J Asiimwe 1, LF Sembajwe 2, A Senoga 1, E Bakiika 1, H Muwonge 2, R Kalyesubula 1,2
PMCID: PMC3824419  PMID: 24250286

Abstract

Background

There is an increase in number of patients with chronic kidney disease (CKD) in Uganda's health facilities looking for different options of preparing matooke (bananas), their staple food.

Objective

To establish and evaluate an effective method of removing potassium from bananas (matooke).

Methods

Bananas were sampled from 5markets in Kampala, Uganda. Deionized water was used to soak the bananas and the potassium concentration was determined using an atomic absorption spectrophotometer in both the bananas and water after soaking for varying time intervals. We also determined the potassium concentrations in the bananas and the water after boiling the bananas at 200 degrees Celsius at intervals of 10 minutes (for 60 minutes).

Results

The potassium concentration did not appear to change on soaking alone without boiling. However, on boiling, the concentration in the bananas decreased from about 1.4ppm to approx. 1ppm after 60min; yet the concentration of potassium released into deionized water increased steadily from 0.0ppm to about 1.2ppm after 60min of boiling.

Conclusion

This study demonstrates that boiling the bananas is a more effective way of removing the potassium from bananas than simply soaking them.

Keywords: Potassium, chronic kidney disease, soaking of bananas before cooking

Introduction

Chronic kidney disease (CKD) is on the increase in Suβ-Saharan Africa, with some countries reporting prevalence as high as 36% amongst high risk populations1. Management of CKD partly involves restriction of Potassium intake due to the anticipated danger of hyperkalemia that may result from either decreased renal function or an increased dietary intake2, 3. The recommended daily intake of potassium among patients with CKD is <4g/day for stage 1 and stage 2 patients, and <2.4g/day for patients with stage 3 and 4 disease4.

Due to the feared risks of hyperkalemia, patients with CKD have been advised to avoid consumption, or eat in moderation foods found to contain high levels (>400mg/100g) of potassium3. Such foods include among others: Matooke (local name for bananas or plantain in Uganda), tubers e.g. potatoes and yams, grains e.g. wheat, and vegetables such as soya beans5.

This often leaves patients with CKD with fewer choices of locally available foods for nourishment and therefore puts them at a higher risk of malnutrition. In addition to lack of food choices and the ensuing chronic inflammation, patients with CKD usually vomit a lot and lack appetite which further worsens the malnutrition6. Studies among patients with CKD in India and Nigeria have reported a high incidence of malnutrition in this patient population7.

In the tropics, plantains are a major source of food and income8 with Uganda alone producing an estimated 10 million tonnes annually9. This accounts for about 15% of the total world plantain output9. Most of the matooke produced in Uganda are consumed locally with over 12 million people (about 40% of the population) depending on the crop as their staple food9. In addition, matooke is the commonly served food to patients admitted with CKD at the Mulago National Referral Hospital Renal Unit. Therefore, many of the patients with CKD continue to regularly eat matooke despite its potential risks. Though it has not been proven, there is some evidence to suggest that the potassium content of most vegetables can be decreased through a process of leaching which entails slicing and soaking of vegetables overnight in water, then draining and boiling the vegetables in new water10. In application of the above principle, patients with CKD are often told to soak the matooke in cold water for about 12 hours prior to cooking. This is aimed at removing the potassium from the intracellular compartments of the bananas11 so that the bananas have less potassium by the time of consumption.

The scientific basis and the optimal recommendations for this practice have never been evaluated and there is no sufficient evidence to suggest that this practice works efficiently.

This study was therefore conducted to establish the effectiveness of this intervention in the removal of potassium from the matooke as well as the optimal time taken for this to happen before it can be deemed safe for consumption by the patients with CKD. The results of this study will inform the scientific community on the effectiveness of the soaking methods in removing potassium from matooke as well as the optimal time and method for performing this intervention.

Methods

Study setting & procedures

The matooke were collected from five different markets in Kampala city of Uganda in order to rule out any regional differences in the mineral content of the same species of plantain. The bananas were taken to the laboratory where they were peeled. Some matooke samples were soaked in cold deionized water after which their potassium content at was determined at different time intervals of; 2hours, 4 hours, 6 hours, 8 hours, 12 hours and 24 hours. The amount of potassium that diffused into the soak water was also determined. Other matooke samples were boiled at 200°C for the following intervals of; 10min, 20min, 30min, 40min, 50min and 60min using a temperature regulated hot plate in the laboratory. The amount of potassium that diffused into the boiling water, as well as that left in boiled matooke was determined at each of those time intervals.

The potassium content of either water or banana tissues, was analyzed and quantified using an atomic absorption spectrophotometer, which is found at the School of Science in Makerere University. A modified protocol for determining potassium concentration using an atomic absorption spectrophotometer was followed, as used elsewhere12. In our protocol, we used a grinder/blender to homogenize the matooke for 5 minutes; we used 30ml/1gm of nitric acid to decompose the matooke in order to pulverize the organic matter; and 2ml/1gm of hydrogen peroxide was used to oxidize and remove organic materials present in the matooke by its “foaming” action. This was all done to ensure complete extraction of potassium from the bananas so that it can be accurately quantified. The concentration of potassium in the matooke or soak-water was then determined against stock standards for potassium.

Data analysis

The analysis was done according to the clusters (or markets where the bananas were obtained). The potassium concentration of the matooke was correlated and plotted against either/ or both the duration of soaking, and/ or the duration of boiling/cooking for each sample, using SPSS (version 17). We run Pearson's correlation, to establish strength of the relationship between the potassium concentration in matooke and the water at the different intervals of time during soaking and boiling.

Ethical approval

The research protocol was approved by the School of Biomedical Sciences-Research and Ethics committee in Makerere University.

Results

Soaking the bananas

On plotting a line graph to show the changes in the concentration of Potassium in water soaked with matooke samples over a time, we observed that the potassium levels rose from 2.2 ppm at 2hours to 4.00 ppm after 6hours, increasing exponentially to 6.08 ppm at 20 hours of soaking. We also observed that there was little effect, if any, of soaking on depletion of potassium from the intracellular compartments of the matooke because the levels of potassium in the matooke samples soaked in water remained constant throughout the 20 hour duration of soaking as shown in table 1 & figure 1. On soaking, it was also noted that the different layers of the matooke kept sloughing off leaving the inner layers firm and intact.

Table 1.

Concentration of potassium in (matooke) & water after soaking (ppm)

Soaking
duration
Samples
2hrs 4hrs 6hrs 8hrs 10hrs 12hrs 14hrs 16hrs 18hrs 20hrs
Water
(av)
2.2 3.6 4 3.24 3.72 4.08 4.48 5.18 5.82 6.08
Bananas
(av)
1.32 1.18 1.274 1.238 1.256 1.326 1.28 1.21 1.24 1.196
Total 3.52 4.78 5.274 4.478 4.976 5.406 5.76 6.39 7.06 7.276

*av = average potassium concentration, ppm =parts per million

Figure 1.

Figure 1

Concentration of potassium in (matooke) & water after soaking

When we run Pearson's correlation, to establish This is a negative correlation co-efficient but a weak strength of the relationship between the potassium one, indicating that though there may be a concentration in matooke and the water at the relationship between time of soaking of matooke different intervals of time during soaking, we got and loss in potassium, the K+ loss-time relation is the correlation ‘r value’= −0.479 (p-value; 0.161). This is a negative correlation co-efficient but a weak one, indicating that though there may be a relationship between time of soaking of matooke and loss in potassium, the K+ loss-time relation is quite non significant.

On boiling the bananas

The matooke from the different markets were boiled at 200 degrees centigrade which is about the average temperature attained from most open air charcoal stoves15 commonly used in Uganda. On heating the samples of matooke collected at different intervals [of 10 minutes for 60min] against the time intervals for the different markets, we noted a progressive decrease in potassium concentrations in the matooke over time, during heating. At the same time, the potassium concentration in the water was noted to increase over time as heating progressed (table 2 & figure 2). After 60 minutes of boiling the levels of potassium in the water changed very little while those in the matooke started increasing.

Table 2.

showing changes in potassium concentration of (matooke) & water after boiling

Bananas/Water samples after boiling (ppm)

Boiling
duration
10min 20min 30min 40min 50min 60min
Bananas (av) 1.35 1.24 1.1 1.04 0.96 0.88
Water (av) 0.08 0.3 0.46 0.58 0.78 0.94
Total 1.43 1.54 1.56 1.62 1.74 1.82

*Av = average potassium concentration, ppm = parts per million

Figure 2.

Figure 2

Changes in potassium concentration of (Matooke) & water after boiling

After running Pearson's on boiling, the r value = −0.99 (p-value <0.001). The correlation coefficient obtained was a perfect negative that is −0.99 which is approximately one.

Discussion

This study has demonstrated that soaking matooke for 2–20 hours to remove potassium so that patients with chronic kidney disease can use it, is ineffective. This was a rather an unexpected finding as it was previously thought that the water would draw out the potassium from the matooke as the time of soaking increased as seen from previous evidence which suggested that soaking vegetables for a period of at least 12 hours in water caused leaching of potassium from the vegetables10. However, the lack of effectiveness of this method could probably be due to the fact that the matooke have different compartments (layers) of potassium as shown by observations made elsewhere13, 16. In our study the different layers of the matooke kept peeling off into the water which could explain why the levels of potassium in the water increased despite constant levels in the matooke. Clearly, this shows that soaking matooke is not an effective way of removing potassium from them.

On boiling the matooke, the level of the potassium from the matooke correlated with that of the boiling water up to about 60 minutes. This negative correlation co-efficiency means that as boiling takes place, potassium loss also occurs at almost the same rate. The coefficient is negative because as the matooke lose potassium, it is gained by the water. So there is decrease in potassium concentrations in matooke and increase in potassium concentrations in the water, in which the matooke was being boiled. Cooking matooke at temperatures above 70°C leads to solubilization of pectin, a major component in the cell walls of banana cells14. This makes the cells more susceptible to rupture which also ultimately contributes to the dissolution of the middle lamella of the banana14, a layer that contains the highest level of potassium in the banana fruit13, 16. This subsequently leads to release of potassium from the banana and hence the observed reduced potassium concentrations in the matooke after 60 minutes of cooking at 200°C in this study.

This study shows that boiling is effective in removing potassium concentrations from the intracellular compartments of the matooke and may be the preferred method of preparation for patients with kidney disease who still want to eat matooke.

Our study had some limitations as it did not evaluate the effect of boiling on the other micro-nutrients which have been found to be plenty in these matooke. We cannot therefore give comments on these other electrolytes. Other studies may look into this aspect as well. We also used temperatures of 200 degrees Celsius which may be on a higher side in an ordinary kitchen cooking environment in Uganda where people use mainly firewood or charcoal to cook their food.

Conclusion

Soaking matooke is not an effective way of removing potassium. Boiling matooke at temperatures of 200 degrees Celsius, for at least or more than 60 minutes, depending on the source of heating used, is an effective way of removing potassium. This method could be recommended for use by patients with chronic kidney disease and hyperkalaemia.

Acknowledgements

We thank the Departments of; Internal Medicine of Makerere University and Medical Physiology in Makerere College of Health Sciences for providing technical support to the study. We are also very grateful for the funding received from MEPI-MESAU consortium which made this research possible.

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