Document Type : Original Article
Authors
1 Graduate student, Nutrition and Food Science Department, Faculty of Home Economics, Helwan University Egypt
2 Department of Nutrition and Food Science, Faculty of Home Economics,HelwanUniversity
3 Department of Nutrition and Food Science, Faculty of Home Economics,Helwan University
Abstract
Keywords
Potential Effect of Sour Orange Peel (Citrus Aurantium) Supplementation on Lipid Profile and Liver Function of Albino Rats Fed on High Fat Diet
Samar, K.H. *; Seham A.M. Tharwat**
andAshraf A. Abdel Megeid**
* Graduate student, Nutrition and Food Science Department, Faculty of Home Economics, Helwan University - Egypt
**Department of Nutrition and Food Science, Faculty of Home Economics,HelwanUniversity - Egypt.
Abstract
The present study was carried out to investigate the effects of supplemented high fat diet (HFD) with two levels (1.5 and 3%) from dried unripe or ripe sour orange peel on serum leptin, glucose, lipid profile and liver functionsof albino rats. A total of 36 male albino rats weighing (40±5g) were used.The rats were divided into two main groups.The first main group (n=6) fed on basal diet (BD) and used as a negative control group (-ve). The second main group 30 rats fed on high fat diet (HFD) and divided into five subgroup. The first subgroup fed on (HFD) all over the experimental period and used as a positive control group (+ve). The other (4subgroups) were fed or (HFD) supplemented with two levels (1.5 or 3%) from dried unripe sour orange peel (DURSOP) or dried ripe sour orange peel (DRSOP) for 8 weeks. At the end of experiment, rats were sacrificed and blood samples were collected, then serum was separated, glucose, leptinlevel, lipid profile as well as AST, ALT and ALP enzymes were determined. The obtained results revealed that feeding 25 days of age albino rats on (HFD) supplemented with (3% from DURSOP or DRSOP) induced a significantdecrease in serum leptin, glucose, total cholesterol (TC), triglycerides (TG), LDL-c, VLDL-c, AST, ALT and ALP, on the other hand significant increase in serum HDL-coccurredin albino rats fed on HFD supplemented with (3%) from (DURSOP) or (DRSOP) followed by group fed on (HFD) supplemented with (1.5%). In conclusion,the results showed that administration of citrus unripe or ripe sour orange peel at levels (3 or 1.5 %) to rats fed on (HFD) could assist in management of obesity and its complications.
Introduction
Over weight and obesity are the fifth leading risk for global death. At least 2.8 million adults die each year as a result of being overweightor obese. In addition, 44% of the diabetes burden, 23% of the ischemic heart disease and between 7 and 41 % of certain cancer burdens are attributable to overweight and obesity (WHO, 2012). In developing countries with emerging economics (Classified by the world Bank as lower and middle -income countries), the rate of increase of childhood, overweight and obesity has been more than 30 % higher than that developed countries (WHO, 2015).
Obesity is a significant and increasing public health problem worldwide. Even through there are several treatments, such as surgery and drugs, there seems to be no efficient treatment without potential side effects., thus considering a life style modification as the best option. In addition to a lifestyle modification, natural alternatives may provide increased health expectancy. Several plants possess anti-obesity potential and have been poorlystudied, while others are not even promoted (Claudia et al., 2015).
Polymethoxy flavones the major components of orange peel have been found to have health benefits including anti-inflammatory, anti-carcinogenic, anti-viral anti-oxidant, anti-thrombogenic and anti-atherogenic properties (Li et al., 2009). Therefore, the present study was carried out to investigate the effects of supplemented HFD with (DURSOP) or (DRSOP) on serum leptin, glucose, lipid profile and liver enzymes of albino rats.
Material and methods
Materials
Sour orange (Citrus aurantium) were obtained from El Abour market. The raw orange ripe and unripe were washed carefully and peel cut into small pieces to be exposed to solar energy at national research center and ground to fine powder.
Chemicals
Casein, vitamins,minerals, cellulose, choline chloride were obtained from Elgomhoria Company, Cairo, Egypt.
Kits for biochemical analysis were obtained from Gamma trade Co-for Pharmaceutical and chemicals. Dokki, Egypt.
Rats
Thirty-six male albino rats of Sprague Dawleystrain 25 days age (40±5 g b.wt) were obtained from the laboratory of animal's colony, ministry of health and population, Helwan, Cairo, Egypt.
Experimental animalsDesign
Rats were housed in individual cages under hygienic laboratory conditions and were fed on basal diet adlibitum for one week for adaptation in the animal house of faculty of Home Economics, HelwanUniversity. The basal diet in the preliminaryexperiment consists of 14 % casein (protein>85%) , corn oil 4%, salt mixture 3.5%, vitamins mixture 1%, choline chloride 0.25%, cellulose 5%and (72.25%) corn starch. Reeves et al., (1993).
The salt mixture and vitamin mixture were prepared according to Hegested et al., (1941) and Campbell (1963). After a period of adaptation on basal diet, rats were divided into two main groups .The first main group (6 rats) fed on basal diet (negative group). The second main group: thirty rats were fed on high fat diet (HFD) all over the experimental period containing (14% protein from casein, 20% fat "19% saturated fat and 1% unsaturated fat", 5% cellulose, 3.5 % salt mixture, 1% vitamin mixture, 10% sucrose , 0.25% choleinchloride and the remainder is cornstarch). Supplementation of diet with dried unripe or ripe dried peel of sour orange was at the expense of starch.
Rats of the second main group were divided into five subgroups. one of them 6 rats was fed on (HFD) used as a positive control group and the other four subgroups were fed on (HFD) containing 1.5% dried unripe peel (DURSOP), 3% (DURSOP), 1.5% dried ripe peel DRSOP and 3% DRSOP, respectively.During the experimental period body weight and food consumption were measured twice a week and total feed intake of the experimental period (8weeks) and body weight gain % were calculated.
Biochemical analysis of serum
At the end of the experiment period, the rats were starved for 12h and then sacrificed under ether anaesthetized. Blood samples were collected from hepatic portal vein by the means of fine capillary glass tubes Schermer, (1967). Blood samples were received into clean dry centrifuge tube and left to clot at room temperature, then centrifuged for 10 minutes at 3000 r.p.m.to separate serum. Serum was careful separated into dry clean Wasserman tubes, using a Pasteur pipette and kept frozen at (-20o C) till estimation of some biochemical parameters.Serum samples used for determination of total cholesterol (Allain et al., 1974), triglycerides (Foster and Dumns., 1973), high density lipoprotein cholesterol HDL-C (Lopes-Virliaet al., 1977).While serum low- density lipoprotein cholesterol (LDL-C) and very low-densitylipoproteincholesterol (VLDL-C) were calculated according to theequation of Friedwald et al., (1972). Serum Aspartate Amino Transferase(AST) and Alaine Amino Transferase(ALT) (Reitman and Frankel, 1957)andAlkalinephosphatase (ALP)(Belfield and Goldberg, 1971).
Statistical analysis:was carried out using SPSS statistical software version 11 (SAS., 2004).
Results and Discussion
Effect of sour orange peel(citrus aurantium) on lipid profile of Albino Rats fed on high fat diet
Table (1&2) Shows the effect of high fat diet (HFD) supplemented with two levels (1.5 or 3%) from dried unripe sour orange peel (DURSOP) or dried ripe sour orange peel (DRSOP) on serum total cholesterol (TC), triglyceride (TG),low-density lipoprotein cholesterol (LDL-C), very low densitylipoprotein cholesterol (VLDL-C) and high density lipoprotein cholesterol (HDL-C) in albino rats 25 days of age fed on (HFD). The mean values of serum total cholesterol and triglycerides significantly (P> 0.05) increased for positive control group, while the mean values of(HDL-c) significantly decreased (P> 0.05), the mean values of(LDL-c) and (VLDL-C)recorded significantly increased (P> 0.05) in the control positive group (fed on high fat diet), as compared to the negative control (fed on BD). In this respect Wu et al., (2013)reported that (HFD) induced increased serum (TG) and (TC) levels compared to those fedon the (LFD).
Our results revealed that all animals groups which fed on (HFD) supplemented with (1.5 or 3%) from (DURSOP or DRSOP), recorded a significant decrease (P> 0.05) in(TC), as compared to the (+ve) control group.Results showed a significant difference between the (-ve) control group and animal group fed on(HFD) supplemented with (3%)from (DURSOP) or (DRSOP) followed by groups fed on (HFD) supplemented with (1.5%) from (DRSOP).
Concerning the (TG) results revealed that groups fed on (HFD) supplemented with (1.5 or 3%) from (DURSOP or DRSOP) recorded significantly decrease (P> 0.05) in (TG)levels.The best results was recorded by group fed on (HFD) supplemented with (3%) from (DRSOP) followed by (3%) from (DURSOP).
The phenolic and flavonoids compounds extracted from (DURSOP and DRSOP) it could be identify 18 fraction, characterizes with high amounts of Naringin, Hespirdin ,Apig 6 rhamnose 8- glucose , Rutin and Quercetrin to be the predominant compounds. Concerning phenolic compounds resulted in 19 fraction, while (DRSOP) showed 21 fraction.The predominant phenolic in (DRSOP) was pyrogallol, whichamounted 9456.49 vs 3541.46 in (DURSOP).The predominant phenolic in (DURSOP), isoFerulic, Benzoic,Ferulic, catechein, P-OH-benzoic, caffeine and 3.4, 5 methoxy-cinnamic. Therefore, our results revealed that Egyptian sour orange peel have considerable number of healthy compounds namely polyphenols and flavonoids. Biological results also showed that the supplementation of (HFD) with (DURSOP or DRSOP) at levels (3 or 1.5%) induced a significant reduction in body weight gain %, organs weight /body weight and peritoneal fat pad %.
In this respect, lee et al., (2015) reported that citrus peel has a potential benefit in preventing obesity through the inhibition of lipogenesis and adipogenesis, Lee suggested that the B-oxidation –related genes were increased in rats fed combination composed of citrus unshiu peel extracts compared to that of animal fed on (HFD).
In this concern kelleya et al., (2013) reported that citrus flavonoids have positive effects against obesity such as lower in LDL-C and (TG). Citrus peel treatment reduced body weight gain and decreasedepididymal fat, mesenteric fat, plasma and hepatic (TG) levels(Karagozlu et al., 2016).
Concerning serum lipoprotein cholesterol resultpresented in table (2) showed the effect of (HFD) supplemented with (1.5 or 3%) from (DURSOP or DRSOP) on serum lipoprotein cholesterol fraction of 25 days albino rats. Our results revealed that all animal groups fed on (HFD) supplemented with 1.5 or 3 % from (DURSOP or DRSOP) showed a significant decrease in LDL-C and VLDL-C, as compared to control (+ve) fed on(HFD).The best results recorded bysupplementation of (3%) from (DRSOP or DURSOP). On the other hand result showed that all groups fed on (HFD) supplemented with (1.5 or 3%) from (DURSOP or DRSOP) recorded a significant increase (P> 0.05) in HDL –C level, while (+ve) control fed on (HFD) recorded a significant decrease (P> 0.05) in HDL-C.
It is known that there is a correlation between lipoprotein cholesterol changes and obesity. In obesity HDL-clevel and elevation of HDL-C is one of the targets for ant-obesity treatment (Vozarova et al., 2002).
Effect of sour orange peel (Citrus aurantium) on serum glucose, leptin and liver functions in albino rats fed on high fat diet
Table (3) illustrate the effect of two levels (1.5 or 3%) from (DURSOP or DRSOP) on serumglucose, leptin, aspartate amino transferase (AST), alanine amino transferase(ALT) and alkalainphosphatase (ALP) levels in serum rats fed on (HFD). The results revealed that the mean values of serum glucose, leptin, AST, ALT and ALP levels for (+ve) control group fed on (HFD) showed highly significant increase (P>0.05), as compared to the negative control group (139.293+5.320mg/dl, 17.925+1.474ng/ml, 148.423+5.678 u/l, 78.476+2.392 u/l and 168.487+4.752 u/l, vs. 77.830+4.508 mg/dl, 5.986+0.297ng/ml, 53.884+2.749 u/l, 20.598+2.035 u/l and 86.967+1.966 u/l, respectively).
Animal groups fed on (HFD) supplemented with (1.5 or 3%) from (DURSOP or DRSOP) recorded a significant decrease (P>0.05) in serum levels of glucose, leptin, AST, ALT and ALP, as compared to the (+ve) control group. The best results recoded by groups fed on (HFD) supplemented with 3% from (DRSOP).
In this respect (Alam et al., 2014) reported that naringin prevented the increase in hepatic marker enzymes activities (AST, ALT and ALP) and reduced the accumulation of lipid deposition and fibrosis in the liver of high carbohydrate, high fat diet fed obese rats. Naringin supplementation also improved the mitochondrial respiration in these rats, suggesting an improvement in mitochondrial compartment dysfunction and lipid energy expenditure by liver.
In conclusion the results taken together indicated that the dried Egyptian sour orange peel (citrus aurantium) as a good sources of phenols and flavonoids incorporate into (HFD) could contribute to potential management of obesity, being beneficial to alleviate the complications present in obesity.
Table (1): Effect of high fat diet supplemented with dried unripe or ripe sour orange peel on serum total cholesterol and triglycerides of 25 days albino rats:
|
parameter Groups |
Cholesterol mg/dl |
Triglycerides mg/dl |
|
|
Control (-ve) group fed on (BD) |
79.574e +3.224 |
39.058f +3.359 |
|
|
Control (+ve) group fed on (HFD) |
150.585a +6.577 |
79.933a +2.600 |
|
|
High fat diet containing |
1.5% dried un ripe peel (DURSOP) |
138.971b +6.891 |
70.915b +4.024 |
|
3%dried un ripe peel (DURSOP) |
125.005c +2.351 |
61.583d +2.467 |
|
|
1.5% dried rip peel (DRSOP) |
130.017c +3.673 |
66.255c +4.322 |
|
|
3% dried ripe peel (DRSOP) |
116.540d +2.685 |
57.162e +2.889 |
|
Values are expressed as means ± SD.
Values at the same column with different letters are significant at P<0.05.
Table (2): Effect of high fat diet supplemented with dried unripe or ripe sour orange peel or serum lipoproteins cholesterol fractions of 25 days albino rats:
|
parameter Groups |
HDL-c mg/dl |
LDL-c mg/dl |
VLDL-c mg/dl |
|
|
Control (-ve) group |
44.755a +3.091 |
27.008f +1.213 |
7.811f +0.671 |
|
|
Control (+ve) group fedon (HFD) |
18.788f +0.823 |
115.810a +6.225 |
15.986a +0.519 |
|
|
High fat diet containing |
1.5% dried un ripe peel (DURSOP) |
24.594e +1.338 |
100.193b +5.891 |
14.183b +0.804 |
|
3%dried un ripe peel (DURSOP) |
32.167c +0.983 |
80.521d +2.525 |
12.316d +0.493 |
|
|
1.5% dried rip peel (DRSOP) |
26.982d +0.687 |
89.784c +2.356 |
13.251c +0.864 |
|
|
3% dried ripe peel (DRSOP) |
34.939b +0.563 |
70.168e +1.565 |
11.432e +0.577 |
|
Values are expressed as means ± SD.
Values at the same column with different letters are significant at P<0.05.
Table (3): Effect of sour orange peel on serum glucose, leptin and liver functions in albino rats fed on high fat diet:
|
parameter
Groups |
Glucose mg/dl |
Leptin ng/ml |
Liver functions |
|||
|
AST U/L |
ALT U/L |
ALP U/L |
||||
|
Control (-ve) group |
77.830e ±4.508 |
5.986d ±0.297 |
53.884e ±2.749 |
20.598f ±2.035 |
86.967d ±1.966 |
|
|
Control (+ve) group fedon (HFD) |
139.293a ±5.320 |
17.925a ±1.474 |
148.423a ±5.678 |
78.476a ±2.392 |
168.487a ±4.752 |
|
|
High fat diet containing |
1.5% dried un ripe peel (DURSOP) |
122.196b ±3.766 |
14.594b ±1.774 |
128.037b ±3.159 |
68.341b ±3.503 |
147.749b ±5.610 |
|
3%dried un ripe peel (DURSOP) |
102.381c ±3.766 |
10.278c ±1.364 |
112.369c ±2.979 |
59.034d ±2.308 |
137.158c ±4.461 |
|
|
1.5% dried rip peel (DRSOP) |
124.193b ±2.556 |
15.024b ±0.859 |
126.777b ±1.009 |
65.005c ±2.879 |
147.897b ±3.005 |
|
|
3% dried ripe peel (DRSOP) |
95.732d ±4.537 |
9.690c ±1.048 |
105.364d ±4.114 |
53.811e ±2.615 |
133.436c ±2.150 |
|
Values are expressed as means ± SD.
Values at the same column with different letters are significant at P<0.05
AST: Aspartate Amino Transferase
ALT: Alaine Amino Transferase
ALP: Alkaline phosphatas
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التأثير المحتمل للتدعيم بقشور موالح البرتقال الحامضي على صورة الدهن ووظائف الکبد في فئران الالبينو التي تتغذى على غذاء عالي الدهون
سمر کمال حسين* – أ.د. سهام عباس محمود ثروت**
أ.د. أشرف عبد العزيز عبد المجيد**
* طالبة دراسات عليا بقسم التغذية وعلوم الأطعمة – کلية الاقتصاد المنزلي
جامعة حلوان
** قسم التغذية وعلوم الأطعمة – کلية الاقتصاد المنزلي – جامعة حلوان
الملخص العربي
أجريت هذه الدراسة لمعرفة تأثير تدعيم الغذاء عالي الدهن بمستويين (1.5 و 3٪) من قشر البرتقال الحامضيالغير ناضج أو الناضج على مستوي الليبتين والجلوکوز وصورة الدهون ووظائف الکبدفي فئران الالبينو. استخدمت في هذه الدراسة عدد 36 فأر من نوع الالبينو أوزانهم (40 ± 5 جرام). تم تقسيم الفئران الي مجموعتين رئيسيتين. المجموعة الرئيسية الأولى (6فئران) تم تغذيتها على غذاء أساسي وتم استخدامها کمجموعة ضابطة سالبة. المجموعة الرئيسية الثانية (30 فأر) تم تغذيتها على غذاء عالي الدهن، وتم تقسيمهم الي خمس مجموعات فرعية. المجموعة الفرعية الأولي تم تغذيتها على غذاء عالي الدهن طوال فترة التجربة وتم استخدامها کمجموعة ضابطة إيجابية. المجموعات الفرعية الأربع الباقية تم تغذيتها لمدة 8 أسابيع على غذاء عالي الدهن والمدعم بمستويين (1.5 و3%) قشور برتقال حامضي مجفف (ناضج وغير ناضج). في نهاية التجربة، تم تخدير الفئران وتم تجميع عينات الدم، ثم تم فصل مصل الدم، وتم تقدير الجلوکوز والليبتين وصورة دهون الدم بالإضافة الي انزيمات الکبد المتضمن (AST, ALT and ALP). أشارت النتائج المتحصل عليها إلى أن تغذية فئران الالبينو التي تبلغ من العمر 25 يوما على غذاء عالي الدهن والمدعم بمستوي (3% قشور برتقال حامضي مجفف غير ناضج أو ناضج) أحدثت تناقصا معنويا في مستوى الليبتين والجلوکوز والکوليسترول والجلسريدات الثلاثية و الکوليسترول الليبوبروتينات منخفضة الکثافة والکوليسترول الليبوبروتينات منخفضة الکثافة جدا ومستويات انزيمات الکبد (AST, ALT and ALP) ، ومن ناحية اخري حدث تزايدا معنويا في مستوى کوليسترول الليبوبروتينات عالية الکثافة في فئران الالبيوا التي تغذت علي غذاء عالي الدهن والمدعم بمستوى 3% قشور برتقال حامضي مجفف (ناضج وغير ناضج)، يليها المجموعة التي تم تغذيتها علي غذاء عالي الدهن والمدعمة بمستوى 1.5%. استخلصت النتائج أن تناول الفئران غذاء عالي الدهن المدعم بقشور البرتقال الحامضي المجفف (الغير ناضج والناضج) بالمستويين (3% أو 1.5%) يمکن ان يساعد في التحکم في السمنة ومضاعفاتها.
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