SQU Journal for Science, 2017, 22(1), 10-15 DOI: http://dx.doi.org/10.24200/squjs.vol22iss1pp10-15 2017 Sultan Qaboos University 10 Morphometry of Organs in Sheep Fed a Diet Containing Tannins and Polyphenols Osman Mahgoub1*, Ibrahim Inwa2, Isam T. Kadim1, Mohamed H. Tageldin1 and Kaadhia Al-Kharousi 1Department of Animal and Veterinary Sciences, College of Agricultural and Marine Sciences, P.O. Box 34, PC 123, Al-Khoud, Muscat, Sultanate of Oman; 2Department of Anatomy, College of Medicine & Health Sciences, Sultan Qaboos University, P.O. Box 35, PC 123, Al- Khoud, Muscat, Sultanate of Oman. *E-mail: osmahgob@squ.edu.om. ABSTRACT: The aim of this study was to use morphometry to investigate the essential organs of sheep fed with non- conventional diets. Twelve male Omani sheep were fed with one of two types of roughages supplemented with a commercial concentrate for 63 days and then slaughtered. The volumes of their kidneys, testes, and livers were measured. Random samples from the organs were fixed in formalin and embedded in paraffin. Random five micrometer sections from each block were stained with hematoxylin and eosin. Images from four random fields were taken from each slide using a digital camera attached to the microscope and then loaded onto a stereology software installed on a personal computer. Morphometric measurements of body organs were taken. Animals fed diets containing tannins had lower final total body weight and lower weights and volumes of their livers, testes and kidneys. There was high variability in the results of intestinal parts measurements, but there was a general trend of the treated animals having higher duodenal and ilial height, villus height, crypt depth and epithelial thickness. The only significant diet effect was higher liver l and lower Vfrac cytoplasm in the control animals than in those treated. The only significant treatment effect on the kidney measurements was a higher tube length/density in treated animals. There were no treatment effects on the testes measurements. The current study indicates that sheep may safely utilize diets containing the levels of polyphenols and tannins used here with no drastic effects on the digestive system and vital organs. Keywords: Oman; Sheep; Tannins; Morphometry. التراكيب الدقيقة ألعضاء جسم الضأن التي تمت تغذيتها على أعالف تحتوي على التانين والبوليفونوالتم تقنية قياس ااستخد عثمان محجوب وإبراهيم إنوا وعصام كاظم ومحمد حسن تاج الدين وكاذية الخروصي كان الهدف من هذه الدراسة هو استخدام تقنية قياس التراكيب الدقيقة لبعض أعضاء الجسم المهمة في الضأن التي تمت تغذيتها على علف غير :ملخصال م يوماً ثم ذبحت بعد ذلك. ت 63تقليدي. تمت تغذية اثني عشر من ذكور الضأن العماني على أحد نوعي علف خشن باإلضافة إلى علف تجاري مركز لمدة في البارافين. تم صبغة شرائح ميكرومترية طمرهاقياس حجم كل من الكلية والكبد والخصية ومن ثم تم أخذ عينات من كل عضو وحفظها في الفورمالين ثم ام كاميرا رقمية اختيرت عشوائياً من كل مكعب بصبغة الهيماتوكسلين واإليوزين. تم أخذ صور من أربع مجاالت عشوائياً من كل شريحة مجهرية باستخد ات موصلة بمجهر ومن ثم تحميلها على برنامج تجسيم حاسوبي على جهاز كمبيوتر شخصي ثم تم أخذ قياسات تراكيب األعضاء. كان وزن جسم الحيوان نه في الحيوانات التي تغذت على التي تغذت على العلف المحتوي على التانين عند نهاية التجربة ووزن وحجم الكبد والكلية والخصية في نهاية التجربة أقل ع كبر في الجزء األول الغذاء العادي. كان هناك تباين كبير في قياسات مناطق األمعاء المختلفة ولكن كانت هناك اتجاه عام بأن الحيوانات المعالجة لها عرض أ وكانت هناك فروقات معنوية بسيطة في قياسين في الكبد وقياس في والثاني من األمعاء والزغابات المعوية وعمق السراديب المعوية وسمك الخاليا الطالئية. ين والبوليفينوالت الكلية بينما لم تكن هناك تأثيرات معنوية في الخصية. بينت الدراسة بأن الضأن يمكن تغذيته بصورة مأمونة على أعالف محتوية على التان ثيرات ضارة على الجهاز الهضمي وبعض األعضاء المهمة في الجسم.على المستويات التي تم استخدامها في هذه الدراسة بدون تأ .عمان ، الضأن ، التانين ، قياس األشكال :مفتاحيةالكلمات ال 1. Introduction ow quality non-conventional feeds (NCF) usually contain high fibre and low protein, minerals and vitamin levels. The NCF feeds usually contain polyphenols and condensed tannins that may cause antinutritional effects [1]. The tannins have been proved to form combinations with proteins in the rumen rendering them unavailable for digestion [2,3]. Tannins interfere with nutrient digestion and promote excretion of endogenous nitrogen in monogastric animals by forming tannin-enzyme complexes [4]. Tannins might also cause physical damage to the digestive system and other vital organs such as the kidney and liver [5,6]. Research has indicated different responses to tannin consumption in various animal species. For instance, oral administration of tannic acid produced coagulative and hemorrhagic necrosis L mailto:osmahgob@squ.edu.om MORPHOMETRY OF ORGANS IN SHEEP FED DIET 11 in the liver of mice but produced no similar effects in sheep [7]. The current study aimed to investigate the effects of feeding feeds containing phenols and tannins on the morphometry of a number of organs in sheep. 2. Materials and Methods Twelve 1-year old male Omani sheep (body weight 31.8 ± 1.2 kg) were fed one of two types of roughage: Rhodesgrass hay (RGH) or urea-treated palm frond (UTPF) for 63 days. Both groups also received 400 g of a commercial concentrate daily. At the end of the feeding period, the animals were slaughtered. The use of experimental animals and the methodology for the trial was approved by the College of Agricultural and Marine Science Research Committee under Project number: SR/AGR/PLNT/01/01. Levels of phenols and condensed tannins were analysed following standard methods [8]. The reference volumes of the kidneys, testes, and liver were estimated using water immersion volumetry [9,10]. Organs including the abomasum, duodenum, jejunum, and ileum were fixed in 10% buffered formalin. Systematic random samples of tissue were embedded in paraffin. Random five micrometer sections were obtained from each block and stained with H&E and then observed with a Leica microscope (microscope specs). Images from four random fields were taken from each slide using an Olympus digital camera (DP12) attached to the microscope. The images were then loaded onto Histometrix, a stereology software (Histometrix MIL6, Kinetic Imaging Ltd UK) installed on an IBM compatible personal computer. The volume density (Vf) of the nucleus in hepatocytes was estimated by point counting by generating an array of random points grid on the image and counting the total number of points,  P, falling within the nucleus and dividing it by the number of points falling within the whole cell [11]. cell nuc nucf P P V    )( (1) The absolute volume of the hepatocyte nucleus (V(nuc)) was determined by the point-sampled intercept method [12]. The four random sections showing whole cells from each animal, an unbiased counting frame with superimposed random test points was applied on each selected section. If a test point fell on a nucleus profile, a line, l0 , in an isotropic uniform direction (IUR) was drawn through the point to the nuclear boundary. The volume of the nucleus, nucV , was then estimated from the following equation:  3 0 3 lV nuc  (2) Estimates of absolute hepatocyte cell volume (V) were obtained by using the volume density of the nucleus, and volume-weighted mean nuclear volume: )( nucV nuc cell V V V  (3) The surface density measurements (SV) of intestinal villi and the filtration barrier of the kidney were estimated by applying line probes on to an image of the villi/glomerulus and counting the intersections between the line probe and villus/glomerular surface  I. The classical relationship which describes SV, the surface density, in terms of the intersection count  I and the total length of line probe, L, is L I S V   2 (4) where Sv is the surface density  I is the number of intersections L is the total length of line probe falling within the object. For the length density measurements (LV,), the probability that a given structure is hit by a randomly positioned and randomly oriented section is proportional to its linear dimension or length. The number of times a linear structure is cut by or intersects a section will depend on the total length of the structure and the area of the section surface. The length density of renal tubules and seminiferous tubules was estimated by counting the number of tubule profiles, Q, in an area of the section. The relationship which describes LV, the length density, in terms of the intersection count Q and the area of the section is A Q L V   2 (5) where Lv is the length density  Q is the number of intersections A is the total area of section. OSMAN MAHGOUB ET AL 12 The volume of renal glomeruli was determined by the point-sampled intercept method [12]. On each of four random sections showing whole glomeruli at a magnification of ×40, an unbiased counting frame with superimposed random test points was applied. If a test point fell on a glomerulus profile, a line, l0, in an isotropic uniform direction (IUR) was drawn through the point to the glomerular boundary. The volume of the glomerulus, GlomV , was then estimated from the following equation:  3 0 3 lV Glom  (6) To study the effects of diet, data were subjected to the analysis of variance using the general linear models procedure in the SAS Windows version [13,14]. Significant differences between treatment means were assessed using the least significant difference procedure at the P<0.05 level. 3. Results Feed analyses indicated that animals fed the urea-treated palm fronds (UTPF) were subjected to a lower nutritional regime compared to those fed the Rhodesgrass hay (RGH) as their diet had a higher fibre content and higher levels of phenols and condensed tannins (Table 1). Table 1. Chemical composition of ingredients of experimental feeds. Feed ingredient Experimental diets Commercial concentrate UTPF RGH DM (g/kg) 862 892 916 Crude protein (g/kgDM) 180 85 10 Ether extract (g/kgDM) 21.5 11 15 Neutral detergent fiber (g/kgDM) 182 740 614 Acid detergent fiber (g/kgDM) 56 580 370 Hemicellulose (g/kgDM) 126 160 243 Ash (g/kgDM) 73 120 95 Ca++ (g/kgDM) 12 7.4 5 PO4(g/kgDM) 8 1.1 0.20 GE (kj/g) 183 192 173 Total extractable phenols a 16.6 112.6 32.1 Extractable condensed tannins b 0 12.8 0 Total extractable phenols expressed as gram equivalent tannic acid/kgDM. b Extractable condensed tannins expressed as gram equivalent leucocyanidins/kgDM. Animals fed UTPF had lower final weight, lower weight of liver, testes and kidney as well as lower volumes for the same organs either in absolute terms or as per kg/BW (Table 2). Table 2. Body organ weight and volume in Omani sheep fed either urea-treated palm frond (Treated) or Rhodesgrass hay (Control) plus a commercial concentrate for nine weeks. Parameter Experimental group PSE Effect of diet Treated Control Final body weight (kg) 31.70 35.92 0.837 ** Liver weight (g) 311.7 388.6 3.33 *** Liver weight/BW 9.7 10.4 0.27 NS Testes weight (g) 110.6 128.3 6.52 * Testes weight/BW 3.4 3.4 0.21 NS Kidney weight (g) 39.0 40.1 1.02 NS Kidney weight/BW 1.21 1.10 0.019 ** Liver volume (ml) 272.7 352.8 10.03 *** Testes volume (ml) 90.0 106.8 8.01 * Kidney volume (ml) 23.3 26.1 2.55 NS PSE : pooled standard error NS : not significant p<0.05; ** p<0.01; *** p<0.001 MORPHOMETRY OF ORGANS IN SHEEP FED DIET 13 There was high variability in the various measurements of organ morphometry including those of intestinal parts. However, there was a general trend of the UTPF fed animals having higher values for duodenal and ilial height, villus height, crypt depth and epithelial thickness (Table 3). Measurements on the jejunum, however, showed an opposite trend with values from UTPF fed animals being significantly lower than those of the control group, and only significant in the villus height. Table 3. Morphometry of the small intestine of Omani sheep fed urea-treated palm frond (Treated) or Rhodesgrass hay (Control) plus a commercial concentrate for nine weeks. Parameter Type of diet PSE Effect of diet Treated Control Duodenum: Duodenum height (um) 979.0 790.2 63.78 0.09 Duodenum villus height 603.5 505.7 54.96 NS Duodenum crypt depth 368.0 285.5 24.15 0.06 Duodenum epithelial thickness 45.0 37.3 4.28 NS Jejunum Jejunum total height 844.5 1066.5 106.52 NS Jejunum villus height 427.8 652.5 59.49 * Jejunum crypt depth 419.5 416.0 50.0 NS Jejunum epithelial thickness 22.3 26.7 1.84 NS Ilium Ilium total height 996.3 969.2 79.83 NS Ilium villus height 507.5 543.2 47.46 NS Ilium crypt depth 489.5 428.7 56.17 NS Ilium epithelial thickness 23.3 26.5 1.47 NS PSE : pooled standard error NS : not significant p<0.05; ** p<0.01; *** p<0.001 There were no significant effects of diet on the morphometry of the liver except for the liver length density which was higher and the volume of fraction cytoplasm which was lower in control animals (Table 4). The only significant treatment effect on the kidney measurements was a higher value of tube length/density in treated vs. control animals. There were no treatment effects on the testes measurements, either for tube volume, length, length/density or number of nephrons per area (Table 4). Table 4. Morphometry of the liver, kidney and testes of Omani sheep fed urea-treated palm frond (Treated) or Rhodesgrass hay (Control) plus a commercial concentrate for nine weeks. Parameter Treatment PSE Effect of diet Treated Control Liver: Volume density (Vf) 2.73 3.53 1.021 ** Volume fraction cytoplasm 0.75 0.65 0.035 * ANON 8.16 10.37 1.14 NS Volume fraction sinus 0.174 0.105 0.064 NS Nuclear size 4.57 4.28 0.789 NS Absolute volume of hepatocyte nucleus 0.14 0.16 0.020 NS Kidney: Tube volume 2.23 2.62 2.537 NS Tube total length (µ) 2.80×1011 2.15×1011 3.36×1010 NS Length density 0.013 0.008 0.001 * Glomeruli number per area 0.00005 0.00004 0.00002 NS Glomeruli size 19140 25133 3873 NS Surface Density 0.089 0.090 0.012 NS Surface area 2.17×10-12 2.3×10-12 4.17×10-12 NS Testes: OSMAN MAHGOUB ET AL 14 Tube volume 9.68 1.07 6.92 NS Tube length 5.41×109 6.19×109 0.901×109 NS Tube length/density 0.0006 0.0006 0.00009023 NS Number/Area 0.0003 0.0003 0.00004 NS PSE : pooled standard error NS : not significant P<0.05; ** p<0.01; *** p<0.001 Table 4. Contd. 4. Discussion The UTPF with its higher fibre content and lower digestibility coefficients resulted in larger volumes of faeces and lower viscosity of gut contents in the sheep, a characteristic of highly fibrous diets [3]. The UTPF also contained higher levels of phenols and condensed tannins, which have been known to have antinutritional effects [2,15]. Animals fed the UTPF consumed approximately 550 g/d of UTPF and therefore, must have ingested considerable amounts of condensed tannins. It has been reported that similar levels of condensed tannins in sheep have reduced protein degradation in the rumen and increased protein flow to the intestine [16,17]. There was an indication of these classical effects of tannin-containing feeds in ruminants from a digestibility trial using UTPF with sheep [3]. Higher levels of nitrogen in the faeces indicate lower nitrogen retention, which is a characteristic of dietary tannins, which bind to proteins in the rumen and consequently reduce digestion and absorption in the gut [2,4,5]. There are also reports that tannins may form complexes with carbohydrates and minerals and consequently inhibit microbial and digestive processes in ruminant animals, resulting in depressed rumen digestive function [2,15]. The low body and organ weights and volumes of the animals fed diets containing tannins was expected as the highly fibrous feeds with anti-nutritional factors would restrict feed intake and consequently negatively influence the body weight of experimental animals. The size of testis is indicative of reproductive efficiency in male farm animals. The weight of the testis of the sheep in the current study was equivalent to 0.35% of body weight. This is in line with observations indicating that testis mass as a proportion of body weight decreases with increasing size of mammals [18]. It has been reported that the gonadosomatic index (testes mass/body mass) in cats was as low as 0.08% [19]. Therefore, it appears that tannin consumption did not directly affect testis size and consequently would not affect reproductive efficiency in male sheep at the levels used in the present study. On the other hand, tannins in monogastric animals produce a significant effect on the weight of some body organs. Some reports have indicated that tannins significantly increase pancreas weight but not liver weight in chickens [20]. In the latter study, the weight of the pancreas from birds which had received the highest amount of tannins was more than double that of the control birds. Significant enlargement was detectable only at tannin concentrations above 13.5 g/kg. As the tannin content increased from 13.5 to 25 g/kg and from 25 to 50 g/kg the pancreas increased in weight by 33 and 10 % respectively. The high variability in the measurements of the organ morphometry in the present study was in line with the conclusion of a prior study that biological variation between individuals is likely to be the major factor influencing the overall precision and efficiency of nested sampling schemes for morphometric analysis of thin sections [21]. Therefore, it was recommended that it is important to examine more animals to reduce the variance of the group mean [21]. Similar to the findings of the current study, there have been reports that duodenal villus height and height to crypt depth ratio were significantly lower in animals fed similar non-conventional feeds [6]. Also there have been findings indicating a trend of decreasing villus height and villus surface area in the proximal duodenum [5]. Conflicting reports on the effects of tannins on the morphometry of the intestine have been attributed to differences in species and to the site of sampling due to the wide variations in intestinal structure along the digestive tract [6]. Villus height and crypt depth decreases from the proximal to the distal regions of the small intestine [22]. The effects on liver morphometry were minimal and may have no biological explanation. Therefore, they were in line with those indicating that oral administration of tannic acid to sheep produced no effects on their livers, unlike inter-peritoneal administration of tannins [7]. The significant treatment effect of the higher values for kidney tube length/density in treated animals may have no serious impact on sheep health with normal glomeruli number and size, as seen in this experiment. The lack of treatment effects on the testes measurements substantiates the observations on testis size and volume discussed earlier on. 5. 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