J. Natn. Sci. Foundation Sri Lanka 2004 32(1&2): 61-68 

DETOXIFICATION OF CASSAVA LEAVES 

A.M.B. PRIYADARSHANI1, E.R. JANSZ", H. PEIRIS1 & S. JAYASINGHE2 
Department of Biochemistry, University of Sri Jayewardenepura. 
Department of Medicine, University of Colombo. 

(Received: 09 December 2002 ; accepted: 25 February 2003) 

Abstract: Goitre has been observed in certain areas of the district of Monaragala, 
Sri Lanka, where cassava leaf is consumed daily This study demonstrates that 
traditional methods of cooking cassava leaf result in considerable residual free 
cyanide. This would justify the conclusion that cassavaleaf consumption causes goitre. 
Two methods have been worked out  to reduce t h e  free cyanide content to a 
non-detectable level (< 0.5 ppm) without reduction of protein content. Both methods 
depend on making use of the endogenous enzyme linarnarase. A method using boiling 
water to set off the hydrolytic reaction is dependent on the fact that the linamarase 
content of the leaves that are used in cooking is of the order of >1 mg CN- mg 
dry wt mi rL .  

Keywords: Cassava, cyanide, detoxification, goitre, Manioc leaf 

INTRODUCTION 

Cassava, Manioc (Manihot esculenta Crantz) tuber is a well known starchy staple 
in Africa.l Many toxic effects arising mainly from thiocyanate resulting from 
metabolism of cyanide have been rep~r ted .~  Thiocyanate which is produced by a 
detoxification mechanism leads to g ~ i t r e . ~  This has been well known for decades 
and is due to inhibition of I- uptake by the iodide pump of the thyroid gland by 
th i~cyanate .~  

There is no report in the literature for goitre being caused by consuming the 
leaf of cassava. This is probably due to the fact that the ,leaf is usually not consumed 
in quantity. A special situation exists in persistently drought stricken areas in 
Monaragala in the South East of Sri Lanka where a District Medical Officer of a 
small hospital in Badalkumbura in the Monaragala district noticed high prevalence 
of goitre and high consumption of cassava leaf (Dr. P.L. Attapattu, private 
communication). 

This unusual situation had arisen due to a combination of drought, poverty 
and ignorance of the existence of cyanogenic glucosides in all parts of the cassava 
plant. The drought contributed to cassava being the most suitable plant to cultivate. 
The cassava tubers are sold and rice is purchased. Their meal thus comprises manioc 
leaf (35-100 g day1) and rice. Poverty restricts the choice of all fish, meat and most 

' Corresponding author 



62 A.M.B. Priyadarshani et al. 

 vegetable^.^ The people of the area consume manioc leaf after cutting it into large 
pieces and mild heat treatment, for fear of loss of vitamins. The combination of 
circumstances has led to 73 cases of goitre being reported to the Base Hospital in 
Sirigala in Monaragala, which serves only a few thousand p e ~ p l e . ~  Cases were mostly 
females (63) of 35-45 years of age. Various degrees of goitre development were noticqd, 
but the rate of development of goitre was not clear. 
The objectives of this study were to: 

(I) Determine the total cyanide content of the correct maturity of leaves that are 
usually consumed. 

(11) Determine residual free and bound cyanide after using traditional methods of 
cooking. 

(111) Determine methods of cooking that would reduce the total cyanide to less 
than 0.5 ppm (detoxification). 

(Iv) Estimate linamarase activity in cassava leaf in order to provide the theoretical 
basis for the detoxification procedure. 

METHODS & MATERIALS 

Cassava leafi The 3'*, 4th,and 5th leaves that are normally eaten, were collected. 
Moisture content was determined by the Dean and Stark method5 and by drying in 
an oven at  105 "C to constant   eight.^ 

Daditional Methods of Cooking: 

(a) "Malluma": Cassava leaves (5 g) were sliced and mixed (1:l) with grated coconut 
and then tempered for 5 min in a pan. 

(b) Cassava leaves (5 g) were sliced and fried in a small amount of coconut oil for 
5 min. 

The products in each case were used to determine the free and bound cyanide. 

Detoxification Methods: 

(a) Cassava leaves were sliced and pounded in a mortar. Thin slices were kept 
for 2 h a t  ambient temperature (29 -30 OC) and analysed for free and bound 
cyanide. 

.(b) Boiling water was poured on to cassava leaf chopped into large pieces 
(10 cm2 leaf). This was left to stand for 2 h until cooking and then analysed 
for free and bound cyanide. All analyses were carried out in duplicate. 

Isolation of Linamarase: 

(a) For use in assays. Cassava rind (200g) was used as the starting material. The 
procedure of Wood7 was used to extract linamarase with the modification of 



Detoxification of Cassava leaves 63 

using 5 mg EDTA. 100 ml-l, 0.1M acetate buffer, pH 5.0 for extraction. The 
rest of the procedure including 70% acetone precipitation and dialysis of the 
dissolved protein precipitate followed that described pre~iously.~.~ 

(b) Determination of activity in leaf 

Cassava leaf (9 g) was pounded using a mortar and pestle and immediately 
extracted with 0.1M acetate buffer pH 5.0 (10 ml containing 5mg. EDTA 100 
ml-I buffer). The homogenate was dialysed for 24 h and centrifuged at 3000 
rpm in a bench top centrifuge. The pellet was washed twice with buffer (20 ml 
each) and the total supernatant was made up to 50 ml using the same buffer. 
This was analysed immediately by the syringe assay (see below). 

Estimation of cyanide in leaf preparations: 

(a) Free cyanide - The products of cooking were distilled (water distilled) into 
6.25 % Na,CO, (25ml) and tested for cyanide by the picrate method.'v8 

(b) Bound cyanide - The product of free cyanide distillation was incubated with 
excess linamarase for 24h. then distilled and estimated as above. 

In both cases a standard curve (r2 = 0.9992) of CN- vs absorbance (nm) was used. 

Estimation of Linamarase activity of leaf: Linamarin was purchased from 
Sigma-Aldrich (USA). Linamarin (25 mg, i.e. approximately Km) was dissolved in 
1 ml of water. This was added into a reaction mixture containing leaf linamarase 
extract (0.2 ml) and buffer (3.8 ml of 0.1 M acetate, pH 5.0). The reaction vessel was 
a graduated syringe (5 ml) closed at its tip with a rubber bung.g At zero time and 5 
minute intervals aliquots of 1.0 ml or 0.5 ml were withdrawn and injected into 0.8% 
Na,CO, (1 ml), saturated picric acid (1 ml) and made up to 5 ml. The reaction mixture 
was then heated in a boiling water bath for 10 min7 and absorbance was measured 
at 530 nm. The cyanide released was calculated using a standard curve containing 
molar equivalent amounts of glucose and CN- (r2= 0.9972). The time course was 
linear and activity of linamarase was calculated. 

Estimation of Protein: Protein of cassava leaf (fresh and treated) was estimated by 
the Kjeldhal methodlo in duplicate. The conversion factor was 6.25. 

RESULTS 

Basic analytical data 

The protein content of fresh cassava leaf was found to be 28% dry weight. Moisture 
content was 89-90%. Total cyanide (bound in free leaf) was in the range of 850 - 950 
mg kg -l fresh weight. 



64 , A.M.B. Priyadarshani et a2. 

Traditional cooking 

Preparation of "malluma" and fried manioc led to decreased total cyanide but free 
cyanide content was well over the limits held permissible (3-5 ppm d a i l ~ ) . ~ . ~  
(Table 1). 

Detoxification processes 

Pounding in a mortar and allowing to stand for 2 h and cooking with coconut scrapings 
(1:l) led to a reduction of total and free cyanide content to < 0.5mg kg1 fresh weight 
of cassava leaf (Table 1). 
The experiment shows that pounding and allowing to stand for 2 h activated a very 
active linamarase. 

Table 1: Free and bound cyanide content in fresh and processed Cassava 
leaf. 

Cassava leaf Free CN- Bound CN- 
(mg kg1 fresh wt) mg kg1 fresh wt) 

Fresh - 893 

"Malluma" 119 540 

Fried 112 531 

Sliced, pounded, ND 
held for 2 h "Malluma" 

Boiling water ND 6.6 
Treatinent "Malluma" 

* Based on Cassava leaf fresh weight 
Results mean of duplicates. 

* ND-Not Detected 

Sensitivity - ~ 0 . 5  mg kg' 

Boiling Water treatment 

A similar lowering was observed on boiling water treatment (Tablel). This 
detoxification does not affect protein level, which is still 28% of dry weight. 

Time Course 

On keeping pounded cassava leaf for 2 h at ambient temperature there was a rapid 
decline in cyanide content, reflecting high linamarase activity even a t  zero time 



Detoxifiation of Cassava leaves 65 

after pounding. Table 2 summarizes the changes in cyanide content that occurs 
with time. 

Table 2: Changes with time, of cyanide content in pounded Cassava leaves 
maintained at ambient temperature. 

Time (h) Total cyanide (mg kg1) 

Drv wt Fresh wt 

' Results based on duplicates 

Activity of cassava linamarase 

Cassava leaf linamarase activity was very high and amounted to >1 mg CN-I g dry 
wt-l min-l. This provided credence to our hypotheses. 

Protein content 

Apparent protein content which was determined by Kjeldhal N' was unaffected by 
treatment despite the loss of CN-, as nitrogen content (% dry weight) is not affected, 
due to acetone which is not nitrogenous also being lost (Table 3). 

Table 3: Protein content of fresh and processed Cassava leaves 

Cassava leaf Protein content (% dry weight) 

Fresh 28.1 

Boiling: wash treatment 28.0 

Mean protein values are those of leaves that are normally used for consumption. Loss of dry weight 
occurs due to both HCN (N=14, MW of HCN=27) and acetone (MW=58). This accounts for constant N 
content as estimated by Yjeldhal on dry weight. Results are a mean of duplicates. 



DISCUSSION 

A.M.B. Priyadarshani et al. 

It is clear that cooking of cassava leafin the traditional method gives not only residual 
high bound cyanide but also unacceptable levels of free cyanide (110-120 mg kg1 
fresh weight), which can lead to chronic cassava toxicity2 in general, including 
g ~ i t r e . ~  On field evidence, this is clearly the cause for high prevalence of goitre in 
the arid areas of Monaragala, Sri Lanka. There is cause to believe that chronic 
toxicity effects, such as ataxic neuropathy, vitamin B,, deficiency disorders2, 
cretinism3, etc., which are less obviously seen than goitre could also be present due 
to the intake of these levels of cyanide.l1+l2 This is especially true as the nutritional 
status of the population is poor. Thus goitre may be the "tip of the iceberg" as far as 
chronic toxicity is concerned. 

However it is clear that due to poverty of the people, simplistic advice such as 
not eating cassava leafis not an option. This is particularly important, as the protein 
content of the leaves that are being used for consumption is around 28%. 

The processes of cooking advocated here can detoxify cassava leaf while not 
affecting its protein content. The methods are simple and easily adaptable. 

Addition of limited amounts of boiling water before cooking is worthy of further 
consideration. For this technique to work, the cassava leaf linamarase must be so 
active that some of it survives denaturation for a finite though short time in order 
to hydrolyse all the linamarin. 

An interesting observation is that pouring boiling water on cassava leaf in a 
cotton wool stoppered vessel does not yield positive result with picrate paper. 
(Dr. L.R. Vilvarajah, 2002 private communication). However if the resulting solution 
is mildly heated, cyanide is then liberated. 

This can be explained with the knowledge that liberation of cyanide is a two step 
proces~.~.~ 

glucose 
/I. 

Linamarin Lb Acetone cyanohydrin hydroxynitrile lyase HCN + 
or heat acetone 

Clearly what is happening is that while the boiling water step allows linamarin 
to form the cyanohydrin, the treatment destroys hydroxynitrile lyase and therefore 
cyanide is not produced until the medium is heated. 



Detoxification of Cassava leaves -67 

However, this is only of academic interest as both (i) the cooking processes 
advocated and (ii) the assays for cyanide, involve heating. The alkali medium of the 
assay also provides conditions for acetone cyanohydrin decomposition. 

Acknowledgement 

The authors thank Ms. S Jayasinghe of the Industrial Technology Institute (ITI) for 
Kjeldhal analysis, Dr. Pubudu de Silva for networking the project, Dr.M.R. 
Chandrasiri, District Medical Officer of the Sirigala Hospital, Dr D.P. Attapattu for 
his initial observations linking cassava leaf consumption with goitre and IPICS, 
Uppsala, Sweden, for financial assistance. 

References 

1 Centro Internationale Agncultur Tropicale (1979). Cassava program Annual 
report. Cali, Columbia pp 589. 

2 Nestel B. & Mackintyre R. (1973). Chronic cassava toxicity, Proceedings of an 
International Workshop Lond, 29-30 January, International Development, 
Research Centre oloe pp 11-162. 

3 Ermans A.M., Mbulanko N.M., Delange F. & Ahawalia R. (1980). Role of 
cassava in the etiology of endemic goitre and cretinism. International 
Development Research Centre 1360e pp13 - 160. 

4 Priyadharshani A.M.B. (2002). Detoxification of Manioc leaf. BScCHons.) 
Dissertation, Faculty of Medicine, University of Sri Jayewardenepura. 

5 AOAC (1984). Official methods of analysis. 14th Edition (Ed. S. Williams) 
Washington D.C, 1984 7:004. 

6 AOAC (1984). Official method of analysis. 14th Edition (Ed. S. Williams) 
Washington D.C 1984, 14:062. 

7 Wood T. (1966). The isolation, properties and enzymatic breakdown of 
l inamarin from cassava. Journal of Science of Food and Agriculture 
17: 85-90. 

8 Pieris N. M., Jansz E.R. & Kandage R.L. (1974). Cyanide content of Manioc 
An enzymatic method of determination applied to processed manioc. Journal 
of the National Science Council of Sri Lanha 2 : 67-76. 

9 Pieris N.M. (1976). Studies of the cyanogenic glucosides and glucosidases of 
Manihot esculenta Crantz. PhD Thesis, University of Colombo. 



68 A.M.B. Priyadarshani et al. 

10 AOAC (1984). Official methods of analyses. 14th Edition (Ed. S. Williams) 
Washington D.C. 1984,14 : 067. 

11 Delange F. & Ahluwalia R. (1982). Cassava toxicity and thyroid - Research 
and public health issues, Proceedings of a workshop. Ottawa, Canada, 31 May- 
2 June 1982, International Development Research Centre 207e pp 1-141. . ., 

12 Delange F., Iteke F.B. & Ermans A.M. (1982). Nutritional Factors involved in 
the goitrogenic action of cassava. International Development Research Centre 
Ottawa, Ontario. ppll-90. 


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