Electromagnetic Modeling of the Propagation Characteristics of Satellite Communications Through Composite Precipitation Layers


Science and Technology, 6 (2001) 39-44 
© 2001 Sultan Qaboos University 
 

Determination of Sugar and Mineral Contents in 
some Omani Fruits 

Salma M Z.Al-Kindy, Abdulrahman O Abdulnour, and Maryam M. Al-Rasbi 

Department of Chemistry, College of Science, Sultan Qaboos University, P.O.Box 36,  
Al-Khod 123, Muscat, Sultanate of Oman 

  والمعادن في الفواكه العمانيةكمية السكرحساب 

عبدالرحمن عبيد عبدالنور، مريم الراسبي,   سلمى الكندي   

المعادن التي تمت دراستها هي الكالسيوم،      .  تـم تحليل مجموعة من الفواكه العمانية لمعرفة كميات السكر والمعادن بها            :خالصـة 
 لقد وجد أن كميات السكر والسكر المختزل مشابهة للكميات التي نشرت مسبقاً والتي              .المغنيسيوم، الصوديوم، البوتاسيوم والفسفور   

لذلك فإنه يمكن تعليل  . أما كميات المعادن فقد أظهرت إختالفاً واضحاً عن تلك التي نشرت مسبقاً           . تمـت دراستها في أماكن أخرى     
 .الت المستخدمةهذا اإلختالف في تركيز المعادن لتركيب التربة والطقس وأنواع السال

 
ABSTRACT: Omani fruits were analyzed for their reducing sugar, total sugar contents and some 
minerals. Among the minerals studied were Ca, Mg, Na, K and P. The amounts of total sugar and 
reducing sugar were within the range of values reported in the literature for the analysis of fruits 
conducted elsewhere. The amounts of the minerals differ from the reported literature values. This may 
be attributed to soil composition, climate and type of cultivar. 
 
KEYWORDS: Omani Fruits, Mineral Sugar.   

1. Introduction 

F ruits and vegetables are important in the Omani diet. Per capita fruit and vegetable consumption in Oman has increased since the 1970’s as a result of the remarkable economic 
and social development that accelerated income growth and caused a substantial change in the diet 
of the population.  The consumption of fruits in 1995 reached more than 90 kg per capita 
(Omezzine, et al 1998). This change is brought about by the increase in consumer awareness 
towards low fat, high mineral vitamin sources of food; fruits and vegetable are usually low in 
calories and fat and have no cholesterol making them healthy additions to our diets. Most fruits and 
vegetables are an excellent source of fiber, vitamins and minerals. 
     Fruits like all living things contain a wide range of different chemical compounds. An 
individual fruit is largely composed of living tissues, which are metabolically active and constantly 
changing in composition. The rate of the extent of such changes depends on the physiological role 
and the stage of maturity of the fruit concerned. These changes are well documented in the 
literature. Ting and Vines (1966) reported an increase in citric acid and malic acid with an increase 
in maturity of citrus fruits. The level of sugar and total acids in cherries was found to increase as 
they approach maturity. A good correlation was found between color and soluble solids 
development. These two indices were found to be the best indicators of maturity for good fresh 
market and canning quality of cherries (Drake, et al 1982; Marshall 1954). 
     The level of sugar content in fruits was reported to be lower in trees with heavy crop as 
compared to trees with a light crop under similar growing conditions (Mattus, 1966). Furthermore 
sugar content was reported to be higher in apple fruits grown in areas of reduced moisture 

39 



AL-KINDY, ABDULNOUR and AL-RASBI 
 

availability, high temperature and high sunlight (Mattus, 1966). Cultivar and storage were found to 
significally influence the content of most sugars in apple juices (Fuleki, 1989).  
     The ash content represents the total amount of mineral matter in fruit material. The most 
abundant individual mineral element in fruit is potassium, the content of which is usually between 
60 and 600mg/100g of fresh material. The potassium in fruit tissues occurs mainly in combination 
with the various organic acids in the cell sap. There is little doubt that the pH of the tissue in fruit is 
controlled by the potassium/organic acid balance. Calcium is mainly associated with the pectic 
materials of the cell wall. Magnesium is especially abundant in chloroplasts as a constituent of the 
chlorophyll molecule. 
     Studies of natural chemical constituents of fruits have important fundamental and applied uses. 
Knowledge of composition is essential in objectively defining and evaluating the quality of fruit 
and fruit products, as they proceed through the channels of commerce. Compositional studies 
provide information about the effects of climate, cultural practices, rootstocks and other biological 
parameters on the properties of fruits. The degree to which mineral content can vary within a plant 
species is illustrated by citrus fruits. For citrus fruits grown in Florida, California, Mexico and 
Brazil, potassium concentrations range from 1520 to 3027mg/L and phosphorous concentration 
from 124 to 309mg/L were reported  (McHard, et al 1980). 
     The ultimate composition of the edible parts of plants is influenced by fertility of the soil, 
genetics of the plants and the environment in which the plant is grown. In this work the nutrient 
composition of Oman fruits is determined. The contents investigated are sugar and minerals. The 
fruit samples studied were those usually used in the average household in Oman for normal 
consumption. No attempt was made to obtain fruits grown from various regions of the Sultanate. 
Hence factors such as pre or post harvest, choice of cultivars, cultural practice, storage conditions 
and growing location were not taken into consideration, although such factors are known to play a 
major role in nutrients content of fruits (Batten 1994, Cookson 1996, Fawzi et al 1996, El-Fouly 
and Shaaban 1999, Shaaban and El-Nour 1996). However, these aspects will be investigated in 
future studies since it is important to decide the localities in which improvements are required.    

2. Experimental 

2.1  Materials 

Fruits locally grown were collected from the Public Authority for agriculture products in 
Ghala. These were: Quince (Cydonia oblongo), Sour Orange (Citrus aurantium), Lime (Citrus 
aurantifolia), Grape fruit (Citrus paradisi), Sweet Orange (Citrus sinensis), Pomelo (Citrus 
grandisi), Coconut (Cocoa Nucifera L), Pomegranate (Punica granatum), Banana (Musa 
acuminata), Melon (Cucumis melo), Nabag (Ziziphus Mauritania, Ziziphus Namulania, Ziziphus 
Spina Christi), Guava (Psidium guavaya) and Papaya (Carica papaya).  All chemicals used were 
of Analar grade and were obtained from BDH chemicals Ltd, Poole, England. Ammonium 
molybdate was purchased from Gaindland chemical company, Sandycroft, Deeside, U.K.  

2.2  Method 

2.2.1  Juice Sample Preparation 

Fresh juice was squeezed from the fresh fruit. Sufficient filter aid was added to form a thin 
paste. The paste was then filtered using a Buchner funnel to obtain the clear fruit juice. 

2.2.2  Whole Fruit Sample 
Fresh fruit samples were weighed, blended with a small amount of distilled water and filtered. 

The filtrate was quantitatively transferred into a 250-ml volumetric flask.  

2.2.3   Preparation of Ash Sample 
Concentrated juice sample (50.00 ml) was placed on steam bath to remove all the water, then 

put in a muffle furnace at 550oC for 10 to12 hours until the ash became whitish in appearance. 6M 

 40



SUGAR AND MINERAL CONTENTS IN SOME OMANI FRUITS  
 

HCl (2ml) was added to dissolve the ash sample. The sample was then transferred quantitatively to 
a 50 ml volumetric flask. 

2.2.4   Determination of total and reducing sugars 
This was carried out according to the method of Lane-Eyron (Ting and Rouseff 1986). 

2.2.5   Determination of mineral elements 
Mineral contents were determined from the ash samples solution. All the samples were 

duplicated and analyzed five times. Analytical results with coefficient of variation (CV) more than 
10 % were rejected. 

Calcium and magnesium were determined by the atomic absorption spectrophotometry model 
AL-PHA 4 UK. Absorbance of the sample was read at 422.7 nm for Ca and 258.2 nm for Mg. The 
ash sample prepared as described above was diluted ten fold with deionized water.  

The determination of sodium and potassium was achieved by flame photometry. (Flame 
Photometer Gallenkamp, model FGA-350-L UK). The ash sample solution was diluted a hundred 
fold for K; the original ash solution without dilution was used for Na determination. 

The determination of Phosphorous was by the colorimetric method using ammonium 
molybdate HCl – solution. (Ting and Rouseff 1986). Absorbance reading of the complex was read 
at 650 nm using spectrophotometer PU 8620 (Phillips). The ash solution was diluted fifty fold. 

3. Results and Discussion 

The highest amount of total sugar content in fruit juice was found in quince and the lowest in 
sour oranges (see Table1). 70% of total sugar found in quince was in the form of reducing sugar. 
The highest percentage of reducing sugar content was found in sour orange while the minimum in 
sweet orange (Table 1). The total sugar found in Omani oranges agreed well with the previously 
reported values (Eskin, 1991) for Florida orange. Among the whole fruits studied, banana has the 
highest total sugar content and guava the minimum (Table 2). Pomegranate exhibited the highest 
percentage of reducing sugar. Fleshy fruits such as melon, ziziphus Mauritania, guava and papaya 
have reducing sugar in the range of 53-56% (Table 2). The results for the total sugar content 
reported here for banana, ziziphus Mauritania, zizphus Nammulania and ziziphus Spina christi are 
in agreement with the previously reported literature values  (Khan, et al 1979).  
 

Table 1: Amount of reducing sugar and total sugar in fruit juices g/100ml. 
 

Fruits Reducing
Sugar 

Sucrose Total 
sugar 

True 
total 
sugar 

% of 
reducing 

sugar 

% of 
sucrose 

CV % 

Quince 8.56 3.63 12.38 12.19 70.2 29.8 0.40 
Sour orange 3.32 0.63   3.98   3.95 84.1 15.9 0.35 
Lime 3.19 1.57   4.84   4.76 67.0 33.0 0.42 
Grapefruit 3.55 2.54   6.22   6.09 58.3 41.7 0.55 
Orange 4.74 3.48   8.40   8.22 57.7 42.3 0.32 
Pomelo 5.81 3.13   9.10   8.94 65.0 35.0 0.61 
Coconut 5.12 1.10   6.28   6.22 82.3 17.7 0.52 

 
     Sugar types and concentrations in fruits affect their taste. Most fruits undergo changes in their 
sugar content during maturity. Hence the monitoring of sugar contents and their respective ratio 
may indicate the level of maturity as well as physiological status during storage. Marshall (1954) 
reported a 200 % increase in sugar contents of cherries during maturity. Similar findings were 
reported for apples and pears (Mattus, 1966). Sugars comprise the most abundant soluble 
carbohydrates in citrus fruits with the exception of acidic citrus fruits such as lemon and lime.  

 41



AL-KINDY, ABDULNOUR and AL-RASBI 
 

During maturation the sugar in the juices of all citrus fruits increases both in concentration and in 
absolute amounts. In mature oranges, total-reducing sugar is approximately equal to sucrose (Ting 
and Rouseff 1986) while in other citrus fruits the amount of sucrose is less. Mature tangerines have 
been reported to contain a higher sucrose content compared to fructose and glucose (Ting and 
Rouseff 1986). The ratios of sugar to sucrose of Oman citrus fruits studied here were substantiate 
the findings of Fuleki (1989) who reported that growing areas did not have a significant effect on 
similar to the values reported by Ting and Attaway, (1971) for mature citrus fruits. These results 
sugar composition of apples. All the values of sugar reported have an error of less than 1.0% with 
CV ranging from 0.4% for pomegranate to 0.6% for quince (n=10).  
 

Table 2: Amount of reducing sugar and total sugar for the whole fruit sample g /100g. 
 

Fruits Reducing  
Sugar  

Total 
sugar  

Sucrose True total 
sugar 

% of 
reducing 
sugar 

% of 
sucrose 

 CV %  

Pomegranate   8.58 11.38 2.66 11.24 76.3 23.7 0.40 
Banana 12.95 19.53 6.25 19.20 67.4 32.6 0.45 
Melon   7.33 14.21 6.54 13.87 52.8 47.2 0.52 
Ziziphus 
(Mauritania) 

  4.69   8.98 4.07   8.76 53.5 46.5 0.61 

Ziziphus 
Namulania) 

   9.45  12.62 3.01 12.46 75.8 24.2 0.58 

Ziziphus (Spina 
Christi) 

 11.48  17.39 5.61 17.09 67.2 32.8 0.32 

Guava    2.87    5.26 2.27   5.14 55.8 44.2 0.38 
Papaya    4.93    9.24 4.09   9.02 54.7 45.3 0.53 

 
Table 3: The amount of mineral elements in fruit juice mg/100 ml. 

 
Fruit  K Na Ca Mg P 
Quince   42.6 13.3 24.3 40.5   8.0 
Sour Orange 102.1 17.2   6.25 52.0   6.0 
Orange    46.3 17.8   5.92 25.0 16.0 
Grape fruit     7.4   8.0 29.0 25.6 22.0 
Pomelo   45.7 13.3 16.5 28.9 12.0 

 
The amount of potassium in the Omani fruit range from 7.4-mg/100 ml for grapefruit juice to 

102.1mg/100 ml for sour orange juice (Table 3). For whole fruit the concentration of potassium 
varies from 1.3 mg/100g for ziziphus Mauritania to 20.2 mg/100 for pomegranate (Table 4). The 
value of potassium for orange juice reported here was much lower than the values reported before 
for Florida and Brazil oranges (McHard, et al 1979). The amounts of potassium obtained from 
Ziziphus was compared with the previously reported values, (Khan, et al 1979). Sour orange is a 
good source of potassium. Individuals with concerns of hypertension are advised to reduce their 
sodium intake and consume foods high in potassium in order to achieve an improved 
sodium/potassium ratio. 

Concentration of calcium ranges from 4.5 mg/100g for pomegranate to 20.5 mg/100g for 
muskmelon. No calcium was detected by our instruments for the ziziphus family and for guava 
(Table 4). The minimum amount of calcium was found in orange and the maximum in grapefruit 
juice.(Table 3).  Calcium and potassium are essential plant nutrients; and their concentrations in the 
juice and in the edible portion of the fruit depends upon the genetic make up, as well as the soil 

 42



SUGAR AND MINERAL CONTENTS IN SOME OMANI FRUITS  
 

characteristics. These elements are essential for human nutrition. Their deficiencies, rather than 
toxicity, are of human health concerns.  

The amount of magnesium(Mg) in fruit juice ranges from 25.0mg/ 100ml in sweet orange to 
52.0mg/100ml in sour oranges. Among the edible flesh fruits papaya contained the maximum 
concentration of the element (36.7 mg/100g) and ziziphus Numulania the minimum (2.6 mg/100g). 
Magnesium is an essential element for human, animal and plant nutrition.  
 

Table 4: The amount of mineral element in whole fruit mg/g. 
 

Fruits K Na Ca Mg P 
Pomegranate 20.2 0.75   4.5 28.7 6.0 
Banana 10.3 0.62   7.0 14.8  32.5 
Musk Melon   4.3 0.03 20.5 23.9 7.5 
Papaya 14.1 0.84   6.4 36.7 9.5 
Ziziphus (Mauritania)   1.3 0.03 -   2.64 3.2 
Ziziphus (Numulania)   1.6 0.70 -   2.58 3.7 
Ziziphus (Spina Christi)   2.3 0.55 -   2.85 1.3 
Guava   2.5 0.09 -   2.94 0.7 

 
Sodium concentration in fruit juice is given in Table 3. The values obtained in citrus fruit are 

higher than previously reported in the literature (McHard, et al 1979). Again it reflects fruit 
characteristics which depend on type of soil and nutritional practices. There was no significant 
difference in the value obtained in the ziziphus locally grown and the literature values (Khan, et al 
1979).  Foods contribute more to the daily intake of sodium than drinking water (NRC 1977). An 
impressive amount of evidence has been accumulated over the last several decades, which suggests 
that sodium taken in excess of physiological needs induce an age–related blood pressure and 
hypertension. 
       Among the fresh fruit juices studied, sour orange contained the smallest amount of 
phosphorous (P) (6mg/100ml) and grapefruit the largest (22 mg/100g). Guava contained only trace 
amount of P while banana had the maximum concentration (32.5mg/100g). Phosphorous is 
essential for bone and teeth mineralization for energy use in ATP, phospholipids and acid-base 
balance.  

Compositional studies of the fruits is important in understanding the biosynthetic and 
regulatory systems of fruits, which in turn determine and control the chemical composition of the 
fruit. Considerable data are available in the literature on the composition of fruits. Yet the 
variability of each constituent may be so great that the data cannot be used for strict control of juice 
composition or for food processing. The mean values of some constituents also vary according to 
the geographical location. It is imperative that a data base on the composition of authentic juice be 
obtained from each fruit growing country using similar approved methods. Data should be 
collected for more than a single season to study the effect of weather. Furthermore, the 
compositional study using similar approved methods should be concurrent with the type of soil, 
fertilization and cultural practice. Most commercial farmers use fertilizers to increase crop 
products. These fertilizers contain plant nutrients, which replenish the soil with the required 
nutrients. However, it is important to study the composition of the soil so as to evaluate the nutrient 
status of the soil and to investigate the bio-availability of both micro and macro elements. Previous 
studies (El-Fouly and Shaaban, 1999) indicated a nutrient disturbance in the horticultural crops 
examined in Salalah region in the Sultanate of Oman. This will affect the composition of fruits 
grown in this region. The ratio of major sugar in fruits is a characteristic feature of the fruit and 
serves as a fingerprint for fruit quality provided the fruits are grown using the same type of soil, 
cultivar and nutritional practice. 

 43



AL-KINDY, ABDULNOUR and AL-RASBI 
 

4. Conclusion 

      The amounts of sugar in Omani fruits studied here were found to be within the range reported 
previously for the same fruits grown elsewhere in the world. However, levels of minerals were 
found to be different.  For example, when compared to Florida oranges, Omani oranges showed 
lower levels of K and P and higher levels of Na. 

The effect of choice of cultivars, fertilization practice and soil of different levels of nutrient on 
fruit composition although important was not carried out. This is intended to form the next study in 
our project to quantify the properties of Oman fruits.  

References 

BATTEN, G. D. 1994 Concentration of elements in wheat grain grown in Australia, North 
America and the United Kingdom. Aust.J.Exp.Agrc-34: 51-56. 

COOKSON, P. 1996. Soil Research in Oman : opportunities and priorities. SQU J. Scientific 
Research-Agriculture Sciences, 1: 25-32.     

DRAKE, S. R., PROEBSTRING E.L. JR and SPAYD, S.C. 1982, Maturity index for the color 
grade of canned dark, sweet cherries. J.Am.Soc.Hortic.Sci.107:180. 

EL-FOULY, M.M. and SHAABAN, M.M.. 1999. Status of some horticultural crops in Salalah 
region, SQU J. Scientific Res.-Agricultural Sciences 4(2): 47-52. 

ESKIN, N. A. 1991. Quality and preservation of fruits. CRC Press Boca Raton Florida. 
FAWZI, A.F.A, SHAABAN, M.M. and ABOU EL-NOUR. Z.A.A.1996. Nutritional status and 

nutrients removed by the fruits of three-mango cultivar grown under farm Conditions. 
J.Agric.Sci., Mansoura University., 12(6): 2301-2317. 

FULEKI, T. 1989. Chemical fingerprinting of fruits. Detection of fraudulent activity in fresh and 
processed fruits in research projects summary Agriculture and Food Research Fund. Pers. 
Comm. 

KHAN, A.A., ASHRAF, M and NASREEN, M.A. 1979. Pharmacognostic studies of selected 
indigenous plants of Pakistan. Pakistan Forest Institute, Peshawar, pp 85. 

MATTUS, G. 1966. Harvest and Postharvest handling of apples, American Fruit Grower 86(8). 
MARSHALL, R.E 1954 Cherries and cherry Products. Intersciences, New York. U.S.A. 
MCHARD, J .A., FOULK, S.J. and WINEFORDNER, J.D.1979 A comparison of trace elements 

contents of Florida and Brazil orange juice. J.Agric. Food Chem., 27:1326-1328. 
MCHARD, J.A., FOULK, S.J., JORGENSEN, J.L., BAYER, S. and WINEFORDBER, J.D.1980 

Analysis of trace metals in orange juice. In Citrus Nutrition and Quality American Chemical 
Society Symposium Series No 143, Washington, D.C, pp363-392. 

NRC 1977 Drinking Water and Heath. National Research Council. National Academy of Sciences, 
Washington, DC. 

OMEZZINE, A., CHOMO, G.V and AL-JABRI, O.1998 Demand Analysis of Selected Fruits and 
Vegetables SQU J. Scientific Res.-Agricultural Sciences 3: 19-26. 

SHAABAN, M.M and ABOU EL-NOUR. Z.A.A.1996 The Nutrient balance in Egyptian clover 
(Trifolium alexandrum) as affected by the yield. J.Agric.Sci., Mansoura University., 21(6): 
2293-2299. 

TING S. V and ATTAWAY J.A 1971. In the Biochemistry of fruits and their Products Vol 1 (A.C 
Hulme Gd) Academic Press London and New York, 107-169.  

TING, S.V and ROUSEFF, R.L 1986. Citrus Fruits and their products analysis and technology. 
Marcel Dekker, New York. 

TING, S.V and VINES, H.M 1966 Organic acids in the juice vesicles of Florida Hamlin oranges 
and Marsh seedless grapefruit. Proc.Amer.Soc. Horti.Sci.88 : 291-295. 

 

Received   29 July 2000  
Accepted   26 November 2000  

 44


	Determination of Sugar and Mineral Contents in some Omani Fruits
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	Óáãì ÇáßäÏí ,  ÚÈÏÇáÑÍãä ÚÈíÏ ÚÈÏ�

	Experimental
	
	2.1  Materials
	Fruits locally grown were collected from the Public Authority for agriculture products in Ghala. These were: Quince (Cydonia oblongo), Sour Orange (Citrus aurantium), Lime (Citrus aurantifolia), Grape fruit (Citrus paradisi), Sweet Orange (Citru
	2.2.1  Juice Sample Preparation

	2.2.4   Determination of total and reducing sugars
	Results and Discussion


	Table 3: The amount of mineral elements in fruit juice mg/100 ml.
	Fruit
	
	Conclusion
	References
	EL-FOULY, M.M. and SHAABAN, M.M.. 1999. Status of some horticultural crops in Salalah region, SQU J. Scientific Res.-Agricultural Sciences 4(2): 47-52.



	ESKIN, N. A. 1991. Quality and preservation of fruits. CRC Press Boca Raton Florida.