Browsing by Author "Mutetikka, D."
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Item Characterization of the Chemical Composition of Raw and Treated Jackfruit (Artocarpus Heterophyllus) and Java Plum (Syzygium Cumini) Beans for Poultry Feeding(Journal of Animal Science Advances, 2014) Ndyomugyenyi, E. K.; Okot, M. W.; Mutetikka, D.The chemical composition of Jackfruit beans (JFB) and Java plum beans (JPB) was investigated to establish their nutritive value for poultry. The beans were soaked in water before subjecting them to the following treatments: fermented in presence of wood ash (SFWA); boiled (SB); roasted (SR); autoclaved (SA); fermented after boiling (SBF); roasted after fermentation (SFR); and a combination of boiling, fermentation and roasting (SBFR). Screening to identify phytochemical compounds and quantify anti-nutrients in the raw beans; determining the content of anti-nutrients in treated beans were conducted. Additionally, proximate composition, minerals, and metabolisable energy (ME) of raw and treated beans were determined. Most (>70%) phytochemical compounds in raw JFB and JPB were anti-nutrients and included sterols, triterpenes, courmarins, tannins, cardiac glycosides, alkaloids, saponins and steroid glycosides. Raw JFB and JPB had 1.11, 2.44% tannins; 1.00, 1.54 % oxalates; 0.754, 0.714% phytates respectively. Tannins in raw JFB were reduced by 88.7, 88.5, 85.9 and 84.5% in SFR, SBF, SB and SBFR treatments respectively. Oxalates in JFB were reduced by 85.3% and 81.2% in SBF and SBFR treatments respectively. Proximate composition, minerals, and ME of raw JFB and JPB was 92.5, 91.0% DM; 15.1, 4.42% CP; 0.983, 0.400% EE; 4.20, 3.44% CF; 3.78, 2.17% ash; 74.0, 88.6% NFE; 13.3, 13.2 MJ/kg ME; 0.456, 0.430% Na; 0.611, 0.481% Ca; 0.222, 0.088% P; 1.53, 0.895% K respectively. The method of treatment had no effect (P˃0.05) on CF of JFB. Method of treatment had a significant (P˂0.05) effect on CP, NFE, ME, DM, ash, P, K, Na, and Ca for JFB. Method of treatment had no significant (P˃0.05) effect on CF and CP for JPB but DM, ash, EE, NFE, ME, P, K, Na, and Ca were affected (P˂0.05). The SBF and SBFR reduced tannins and oxalates from raw JFB by more than 80%. The major nutrient in JFB and JPB is energy.Item Dynamics of Cyanogens and In-Vitro Degradability of Cassava Peels as an Indicator of its Nutritional Value as Animal Feed(Livestock Research for Rural Development, 2015) Taabu, H.L.; Ndyomugyenyi, E.K.; Mutetikka, D.; Wasswa, D.The in-vitro degradability of cassava peels and its relationship with the cyanogenic potential of five cassava varieties grown in Uganda was investigated to study the potential of cassava peels as an energy source in animal feeds. The cassava varieties included NASE 3, NASE 4, NASE 10, TME 14 and Tongolo. The first four varieties were considered to be of low to medium cyanogenic potential (CNp), while the last one contained high CNp. Cassava peels had 25.5 ± 6.6% dry matter (DM), 86.6 ± 0.9% organic matter (OM) and 56.8 ± 5.8% neutral detergent fibre (NDF). Degradability of DM, OM and NDF was 74.8± 4.2%, 74% ± 7.5% and 44.2 ± 7.5% respectively. Total cyanogenic potential and free hydrogen cyanide (HCN) in the fresh peels ranged from 923 to 2815 and 33 to 676 mg HCN equivalent kg-1 DM respectively. These levels dropped by 27- 88% and over 90% respectively, when the peels were dried. For all varieties, the residual cyanogenic potential after drying the peels fell within the safety limits recommended by FAO/WHO for food and feed. The study showed that using fresh peels in sufficient amounts for feeding animals, particularly monogastrics, is potentially harmful due to high cyanogenic potential. Drying the peels can, however, reduce the cyanide toxicity risks. The low NDF degradability reduces the nutritional value of cassava peels if they are used as a sole source of energy in ruminant diets.Item Effect Of Feeding Sweet Potato Vine-Based Diets as Partial Milk Substitutes for Dairy Calves in Uganda(Livestock Research for Rural Development, 2016) Taabu, H.L.; Ndyomugyenyi, E.K.; Mutetikka, D.; Ebong, C.A study was conducted to determine the potential of sweet potato vine-based diets as partial milk substitute (PMS) for dairy calves. Twenty five Friesian bull-calves weighing 38.7 ± 4.56 kg were fed composite meals containing 0, 30, 40, 50 and 60% air-dried sweet potato vines (SPV) as partial milk substitutes in a completely randomized design (CRD) over a seventy day period. Dietary treatments were introduced 15 days after calving. Milk offered was reduced by one litre every fortnight until 70 days after birth. Proximate and mineral analyses were carried out for ingredients and dietary treatments. Feed intake (FI), average daily weight gains (ADG), feed: gain ratio and variable cost per unit of gain were computed over the experimental period.Item Evaluation of the Nutritional Value of Soaked-Boiled-Fermented Java Plum (Syzygium Cumini) Seed Meal for Poultry(African Journal of Agricultural Research, 2016) Ndyomugyenyi, E. K.; Okot, M. W.; Mutetikka, D.Chemical analysis, apparent metabolizable energy (MEn), and one feeding trial were conducted to evaluate the nutritional value of Java plum seeds (JPS) that had been subjected to a combination of soaking, boiling, and fermentation (SBF). Five broiler starter diets were formulated with the processed Java plum seed meal (JPSM) comprising 0, 80, 160, 240, and 320 g/kg of the diet. The JPS before and after processing contained 910±5.30 and 888±6.10 g DM; 44.2±0.940 and 48.1±1.02 g CP; 886±9.90 and 888±6.54 g NFE; and 13.2± 0.165 and 13.3±0.154 MJ calculated metabolizable energy; 24.4±1.33 and 9.17±0.940 g tannins per kg, respectively. The MEn value of the processed JPSM was 14.7±0.973 MJ/kg. Feed intake (FI), weight gain (WG), and feed efficiency (FCR) of broiler chicks decreased (R2 ˃ 0.850) with increasing JPSM in the diet. At 80 and 320 g/kg inclusion, FI, WG, and FCR were depressed by 16.0 and 34.1%, 20.2 and 42.5%, and 4.90 and 12.5%, respectively. Liver, heart, and pancreas weights relative to body weight were not significantly (P ˃ 0.05) affected. However, caecum, gizzard, and intestine weights increased (R2 ˃ 0.800), while the heart weight decreased (R2 = 0.772) with increasing JPSM in the diet. At 80 and 320 g/kg JPSM inclusion, weights of caecum, intestine, and gizzard increased by 48.5 and 68.2%, 18.8 and 43.5%, and 9.55 and 19.2%, respectively. Inclusion of JPSM in chick diets adversely (P < 0.05) affected nitrogen retention (NR), nitrogen digestibility (ND), dry matter digestibility (DMD), and excreta water content (EWC). At 320 g/kg JPSM inclusion, NR, ND, DMD, and EWC were depressed by 30.8, 12.6, 0.42, and 2.45%, respectively. No mortality was recorded at 320 g/kg JPSM inclusion. The SBF did not improve the nutritional value of JPS for poultry production.Item The Nutritional Value of Soaked-Boiled-Fermented Jackfruit (Artocarpus Heterophyllus) Seed Meal for Poultry(Journal of Animal and Poultry Sciences, 2015) Ndyomugyenyi, E. K.; Okot, M. W.; Mutetikka, D.Chemical analysis, apparent metabolizable energy and one feeding trial were conducted to assess the nutritional value of jackfruit seeds that had been subjected to a combination of soaking, boiling, followed by fermentation. In the feeding trial, five broiler starter diets were formulated with the processed jackfruit seed meal constituting 0, 80, 160, 240 and 320 g/kg of the diet. The jackfruit seeds before and after processing contained 151, 140 g crude protein; 740, 747 g total carbohydrates; 11.1, 1.28 g tannins; 10.0, 1.47 g total oxalates per kg respectively. The apparent metabolizable energy value of the processed jackfruit seed meal was 2368±315 Kcal/kg. Inclusion of the processed jackfruit seed meal affected chick growth, nutrient utilization and organ weights relative to body weight. At 80 and 320 g/kg inclusion, weight gain and feed/gain were depressed by 5.2, 42.1%; 6.2, 40.7% respectively. Feed intake was not affected up to 240 g/kg inclusion but reduced by 18.3% at 320 g/kg. Except for gizzard; weights of liver, caecum, heart, intestines and pancreas were affected. At 80 and 320 g/kg inclusion; weights of caecum, intestine, pancreas and gizzard increased by 69.4, 113.9%; 4.5, 43.2%; 7.3, 46.3%; 11.3, 14.6%, while liver and heart were reduced by 7.7, 22.2%; 27.9, 34.2% respectively. Apart from nitrogen retention; nitrogen digestibility, dry matter digestibility and excreta water content were not affected. Nitrogen retention increased by 38.5% at 320 g/kg inclusion. Processing reduced tannins and oxalates from jackfruit seeds by over 85%. The processed jackfruit seed meal can be included in poultry diets at levels up to 80 g/kg without compromising with: feed intake, feed efficiency, daily weight gain and nutrient utilization. Although the cost per kg gain of birds increased with jackfruit seed meal inclusion, the seeds will eventually be readily available at low or no cost. However, for economic efficiency the cost of collection and treatment should be put into considerationItem Production and Availability of Jackfruit (Artocarpus Heterophyllus) and Java Plum (Syzygium Cumini) Beans for Livestock Feeding in Eastern and Central Regions of Uganda(Livestock Research for Rural Development, 2014) Ndyomugyenyi, E.K.; Okot, M.W.; Mutetikka, D.A survey was conducted in the districts of Kampala and Mbale between January and March, 2014 to establish the availability of Jackfruit (JF) and Java plum (JP) beans for poultry feeding. Distribution and productivity of JF and JP trees, interest in the trees, and research that had been done on the trees were also determined. A total of 111 respondents, which included researchers, extension workers and household members were used for the study in two sub-counties from each district. Data were collected using structured questions, observations, and interviews. Secondary sources of data were also reviewed. All respondents knew JP and JF trees; all respondents were interested in the trees, and acknowledged that they discarded the beans as waste. The majority of respondents (72%) indicated that JP and JF trees produced fruits twice a year. More JP trees were found in periurban than rural areas, while the number of JF trees in rural areas did not differ much from those in peri-urban areas. Respondents who had JF trees in their gardens were more (74%) than those with JP trees (58%) but the difference was not significant. The same applied to the number of respondents who purposely grew JF trees being higher (32%) than those who purposely grew JP trees (16%) but the end result of the two groups did not differ much from each other. Of the total respondents who had JP trees in their gardens, 27.6% of them purposely grew the trees using seedlings from nursery beds while 43.2% of the respondents had JF trees grown using the seedlings from the nursery beds. The remaining respondents had JP and JF trees grown naturally in the gardens. The JF trees produced significantly more beans (390kg per tree annually) than JP trees (140kg per tree annually). The annual Jackfruit bean production in the 50 villages covered was 10.3 x 10 2 tonnes while Java plum produced 249 tonnes of beans annually. The major limitations to JP and JF production were caterpillar infestation (34%) and injuries caused by accidental falling of children from JP trees (21.3%). Respondents (83.3%) indicated that little research in Uganda had been conducted on JP beans but some work (12.5%) had been done on JP beans and other parts of JP tree to establish their medicinal properties. To ensure constant production of JP and JF beans; multiplication/breeding of the trees, promoting production of the