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Kerala Agricultural University, Thrissur

The history of agricultural education in Kerala can be traced back to the year 1896 when a scheme was evolved in the erstwhile Travancore State to train a few young men in scientific agriculture at the Demonstration Farm, Karamana, Thiruvananthapuram, presently, the Cropping Systems Research Centre under Kerala Agricultural University. Agriculture was introduced as an optional subject in the middle school classes in the State in 1922 when an Agricultural Middle School was started at Aluva, Ernakulam District. The popularity and usefulness of this school led to the starting of similar institutions at Kottarakkara and Konni in 1928 and 1931 respectively. Agriculture was later introduced as an optional subject for Intermediate Course in 1953. In 1955, the erstwhile Government of Travancore-Cochin started the Agricultural College and Research Institute at Vellayani, Thiruvananthapuram and the College of Veterinary and Animal Sciences at Mannuthy, Thrissur for imparting higher education in agricultural and veterinary sciences, respectively. These institutions were brought under the direct administrative control of the Department of Agriculture and the Department of Animal Husbandry, respectively. With the formation of Kerala State in 1956, these two colleges were affiliated to the University of Kerala. The post-graduate programmes leading to M.Sc. (Ag), M.V.Sc. and Ph.D. degrees were started in 1961, 1962 and 1965 respectively. On the recommendation of the Second National Education Commission (1964-66) headed by Dr. D.S. Kothari, the then Chairman of the University Grants Commission, one Agricultural University in each State was established. The State Agricultural Universities (SAUs) were established in India as an integral part of the National Agricultural Research System to give the much needed impetus to Agriculture Education and Research in the Country. As a result the Kerala Agricultural University (KAU) was established on 24th February 1971 by virtue of the Act 33 of 1971 and started functioning on 1st February 1972. The Kerala Agricultural University is the 15th in the series of the SAUs. In accordance with the provisions of KAU Act of 1971, the Agricultural College and Research Institute at Vellayani, and the College of Veterinary and Animal Sciences, Mannuthy, were brought under the Kerala Agricultural University. In addition, twenty one agricultural and animal husbandry research stations were also transferred to the KAU for taking up research and extension programmes on various crops, animals, birds, etc. During 2011, Kerala Agricultural University was trifurcated into Kerala Veterinary and Animal Sciences University (KVASU), Kerala University of Fisheries and Ocean Studies (KUFOS) and Kerala Agricultural University (KAU). Now the University has seven colleges (four Agriculture, one Agricultural Engineering, one Forestry, one Co-operation Banking & Management), six RARSs, seven KVKs, 15 Research Stations and 16 Research and Extension Units under the faculties of Agriculture, Agricultural Engineering and Forestry. In addition, one Academy on Climate Change Adaptation and one Institute of Agricultural Technology offering M.Sc. (Integrated) Climate Change Adaptation and Diploma in Agricultural Sciences respectively are also functioning in Kerala Agricultural University.

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1976 - 19793
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Subject: Dairy Science × End date: 1979 × Start date: 1970 × Type: Thesis ×
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    ThesisItemOpen Access
    Studies on the influence of tannins on nucleic acid and protein syntheses in ruminants
    (Faculty of Dairy and Animal Husbandry, Haryana, 1976) Sadanandan, K P; KAU; Arora, S P
    A study was conducted to elucidate the influence of tannins on synthesis of nucleic acids and protein in liver of rats. In vitro and in vivo studies in buffaloes were also conducted to ascertain the effect of tannins on rumen metabolism. In experiment 1, 30 weanling rats were distributed into three groups of 10 each in a randomized block design. The influence of addition of 0% (group A), 2.5% (group B) and 5% (group C) tennins in the feed on feed consumption, growth rate, nitrogen and dry matter digestibility was investigated. Further RNA, DNA and protein in liver were estimated to asses liver function. The feed consumed daily on DM basis (g); weight gain per three day interval (g); and gram feed per gram weight gain, respectively for groups A, B and C were : 20.05 + 7.6, 7.87 + 0.41, 2.73 +0.05; 16.66 + 6.0, 5.69 + 0.35, 3.14 + 0.07 and 16.11 + 5.4, 4.53 + 0.21, 3.80 + 0.11. The DM and N digestibility (%), respectively for groups A, B and C were: 78.56 + 0.44, 78.28 + 0.56; 78.62 + 0.64, 73.50 + 0.86 and 78.82 + 0.52, 69.97 +0.75. Feed consumption in group A was significantly (P <0.01) higher than in group B and C. The difference in feed consumption between groups B and C was not significant. Significant differences were found amongst all treatment groups in weight gain (P< 0.05) and food : gain ratios (P < 0.01). DH digestibility did not reveal any significant difference between groups whereas the differences in N-digestibility were significant (P<0.01). The addition of tennis in the diet significantly depressed feed consumption, weight gain, and N – digestibility which resulted in widened feed : gain ratios. The average liver weights (g): total protein (mg) ; RNA (mg) and DNA (mg), respectively for groups A, B and C were : 3.61 + 0.21, 717.3 + 4.76, 21.42 + 1.41, 5.36 + 0.41, 2.85 + 0.23, 569.0 + 4.31, 16.40 + 1.60, 4.29 + 0.45 and 2.44 + 0.01, 507.9 + 2.55, 13.79 + 0.58, 3.34 + 0.16. The liver weight in group A was significatly (P<0.05) higher than in group C. The total protein content in group A was significatly (P<0.01) higher than in group B and C. But the difference between groups B and C was not significant. RNA and DNA contents differed significantly (P<0.01) amongst the three groups. The average protein (mg), RNA (mg) and DNA (mg), respectively for the groups A, B and C were : 198.69 + 3.31, 5.93 + 0.18, 1.48 + 0.05, 199.89 + 5.14, 5.68 + 0.16, 1.49 + 0.06 and 208.16 + 2.32, 5.66 + 0.03, 1.38 + 0.04 per gram of tissue. There were no significant differences in the parameters studied amongst the three groups. The body weight : liver weight ratios, protein : RNA ratios and protein : DNA ratios, respectively for groups A, B and C were : 29.0 + 2.23, 33.2 + 1.01, 134.9 + 5.04, 30.3 + 2.45, 35.4 + 1.22, 136.7 + 5.75 and 31.0 + 2.66, 36.9 + 1.01, 153.7 + 4.17. There were no significant differences amongst the ratios except that protein : DNA ratio in group C was significantly (P<0.05) wider than in group A and B indicating probable hypertrophy of liver cells in that group. It was apparent that tannins exerted their harmful effects by affecting protein digestibility in the gastro-intestinal tract and thereby adversely affected liver size and growth rate. In experiment 2, in vitro trials were conducted by taking buffalo rumen liquor through a rumen fistula on a control ration without tannic acid. For N solubility and DH digestibility studies, the substrate used was : Maize, 50 parts ; grount nut cake, 21 parts and wheat bran 26 parts, ground into 40 mesh size. To study the influence of tannins on protein synthesis, nucleic acid synthesis and production of VFA, the substrates used were : cellulose 0.75 g. starch 0.25 g and ammonium sulphate 151 mg. McDougall’s artificial saliva was used as buffer (PH 6.8) for 32 P uptake by rumen microbes, the substrate was prepared from glucose 600 mg and ammonium sulphate 85mg. A mineral solution containing cysterine – HCL described by Bucholts and Bergan (1973) was used as a buffer. The levels of tannic acid, respectively in groups 1,2,3,4 and 5 were : 0, 1.25, 2.5, 5.0 and 7.5% in all the experiments. The E solubility and DM digestibility (%) respectively, for treatments 1,2,3,4 and 5 were : 36.72 + 0.425, 43.80 + 2.63 : 24.48 + 0.311, 37.60 + 2.14, 20.81 + 0.589, 30.27 + 1.85 : 17.55 + 0.312, 21.89 + 1.93 and 15.30 + 0.473, 13.20 + 1.15. Addition of tannins depressed N solubility and DM digestibility. The protein – N (mg) ; RNA – N (mg): DNA-N (mg) and TVFA (meq) (all per 100 ml) respectively for treatments 1,2,3,4 and 5 were : 30.19 + 1.274, 2.156 +0.107, 0.795 + 0.054, 15.46 + 0.315, 23.84 + 1.021, 1.565 + 0.101, 0.561 + 0.025, 12.34 + 0.194, 18.59 + 0.582, 1.185 + 0.046, 0.426 +0.021, 9.38 + 0.425, 16.27 + 1.318, 1.00 + 0.042; 0.337 + 0.013, 7.29 + 0.359 and 14.61 + 0.271, 0.865 + 0.034, 0.290 + 0.006, 5.49 + 0.235. Addition of tannins significantly (p<0.01) depressed all the parameters studied and in treatment 5, the levels were more or less the same as in 0 hour control indicating complete inhibition of microbial multiplication at 7.5% tannic acid level. The RNA –N : protein – N, DNA – N: protein – N and total nucleic acid – N: protein – N ratios respectively for treatments 1,2,3,4 and 5 were : 0.072 + 0.0018, 0.026+ 0.0013, 0.098 + 0.0015, 0.066 + 0.0018, 0.023 + 0.0045, 0.089 + 0.0022; 0.064 + 0.0018, 0.023 +0.00084, 0.087 + 0.0024, 0.062 + 0.0016, 0.021 + 0.00077, 0.082 +0.0020 and 0.058 + 0.0013, 0.020 + 0.00055, 0.078 + 0.0016. The ratios were narrower in control group when compared to tannic acid groups. With regards to 32P uptake by rumen microbes, a progressive decrease was observed with increase in tannin concentration. 32p uptake (mg) per 100 ml respectively for groups 1,2,3 and 4 were : 2.640, 1.835, 1.202 and 0.52. In group 5 there was no 32P uptake. Tannins depressed microbial multiplication indirectly by making the protein source not available due to its precipitation. Direct harmful effect was also possible on microbes, especially, at higher concentrations of tannins in the media without any protein source. In experiment 3, four adult fistulated female buffaloes were randomly distributed in a Latin square design. The treatments I, II, III and IV respectively contained 0, 1.25, 2.5 and 5% tannins made available from 0, 14, 28 and 40% salseed meal in the ration. In treatment IV, 1.436% pure tannic acid was also added to get 5% total tannins. The DCP and TDN contents were approximately 14 and 72% in all the rations. The effect of tannins in feeds was determined through the levels of protein –N, RNA – N, DNA –N and TVFA. The protein –N, RNA – N and DNA-N levels ( all in mg per 100 ml of SRL) and TVFA levels ( meq/100 ml of SRL), respectively for treatments I,II,III and IV were : 43.73 + 1.813, 3.86 + 0.134, 1.63 + 0.053, 9.59 + 0.205; 49.087 + 1.912, 3.75 +0.115, 1.59 + 0.057, 0.43 + 0.215, 54.86 + 1.850, 3.62 + 0.089, 1.50 +0.041, 9.20 +0.188 and 61.89 + 2.050, 3.26 + 0.097, 1.37 + 0.046, 8.48 + 0.283. Protein - N level in treatment L was significantly (P< 0.05) lessthan in ratios II, III and IV and there was a progressive and significant (P< 0.05) increase in order of treatments. RNA – N and TVFA levels in treatment I were significantly higher (P< 0.01) than in treatment IV. DNA levels were significantly lesser (P<0.05) in treatment III than in treatment I and again lower in treatment IV than in treatment III. Nucleic acid - N : protein – N ratios is SRL respectively for treatments I, II, III and IV were : 0.125 + 0.0012, 0.108 + 0.0020, 0.093 + 0.0026 and 0.072 + 0.0011. The ratio in treatment L was significantly higher than in treatments II, III and IV. The differences amongst the four treatments were significant (P<0.01). Addition of tannins in the rations resulted in an increase in protein - N, but progressively depressed the RNA – N and DNA – N levels with less production of TVFA. Further in experiment 3, the protein - N, RNA – N and DNA – N contents of bacteria separated from SRL were also determined to ascertain the effect of tannins on RNA – N: protein – N; DNA – N : protein – N and total nucleic acid : protein - N ratios. Protein – N (mg), RNA – N (mg); and DNA –N (mg) in bacteria separated from 100 ml SRL respectively for treatments I, II,III and IV were : 23.93 + 0.571, 2.385 + 0.87, 1.204 + 0.036, 23.71 + 0.627, 2.296 +0.062, 1.180 + 0.019, 22.79 +0.590, 2.230 +0.044, 1.111 + 0.059 and 20.91 + 0.544, 205 + 0.046, 1.010 + 0.053. Protein -N, RNA –N and DNA – N levels decreased as levels of tannins in rations increased. But the differences were significant (P<0.01) only between treatment I and IV. RNA – N : protein - N, and total nucleic acid – N : protein – N ratios respectively for treatments I, II, III and IV were : 0.099 + 0.0030, 0.150 +0.0027; 0.097 + 0.0023, 0.147 + 0.0029; 0.098 + 0.0024, 0.147 + 0.0017 and 0.098 + 0.0020, 0.146 +0.0025. The differences in the ratios amongst the different treatments were not statistically significant. The addition of tannins at the levels tried had no significant influence on the nucleic acid – N : protein – N ratios in the bacteria. From the value obtained for nucleic acid – N and nucleic acid – N : protein – N ratios in separated bacteria, the microbial contribution of protein - N to the tungestic acid precipitate of SRL was calculated. The values obtained were : 83.67, 74.01, 63.58 and 51.14 % for treatments I,II,III and IV respectively. The tannins present is the feed partially protected the proteins from microbial attack and hence the contribution of dietary protein - N in the SRL increased. Simultaneously the quantity of microbial protein synthesis decreased due to the limitations imposed by tannins on microbial multiplication.
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    ThesisItemOpen Access
    Evaluation of coffee husk for milk production in cows
    (Department of Dairy Science, College of Veterinary and Animal Sciences, Mannuthy, 1979) Geevarghese, P I; KAU; Subramaniam, M
    An investigation was carried out to find out the feeding value of coffee husk for milk production in cows using a total of nine Sindhi x Jersey cross bred cows, divided into three groups of three animals each. The experiment was for a period of 90 days. Coffee husk was included in the concentrate mixture at 0, 10 and 20 per cent levels. A switch – over design was used for the experiment. Coffee husk fed at 10 and 20 per cent levels in the concentrate ration did not significantly influence the body weight of animals. The total milk production of the animals getting coffee husk in the ration did not significantly differ from that of the animals on the control diet. The percentage of fat in milk, the total quantity of milk fat produced, the amount of four per cent fat – corrected milk, the percentage of total solids, the amount of total solids in milk, percentage of solids – not –fat, total quantity of solids – not – fat and the amount of solids – corrected milk remained the same for all the three groups of animals included for the study and no significant differences were noticed due to treatments. The physiological status of the cows in all the groups was normal and satisfactory. No significant difference due to treatments was noticed in some of the physical and chemical constants of butter fat. The dairy merit (percentage) based on efficiency of feed conversion was less of animals getting ten per cent coffee husk due to the reduced milk production and the greater feed consumption. The total cost of feed for producing one kg milk was Rs.1.42, 1.38 and 1.33 for animals getting 0, 10 and 20 per cent coffee husk in the concentrate mixture respectively. It was concluded that coffee husk upto 20 per cent level can profitably be incorporated in the concentrate mixture of dairy cows.
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    ThesisItemOpen Access
    Study of the calf starter with locally available feed ingredients
    (Department of Dairy Science, College of Veterinary and Animal Sciences, Mannuthy, 1978) Francis, U T; KAU; Subramanyam, M
    An investigation was carried out to compare the physiological status and performance of the calves fed two different kinds of calf starters. The calves fed with whole milk and concentrates were used as the control. A total of 18 crossbred calves of the University Livestock Farm, Mannuthy, immediately after birth were assigned at random to one of the following three groups. Group I (control), group II (fed with calf starter I) and group III (fed with calf starter II). There were one male and five female calves in each group. The two calf starters used for the experiment contained 24 per cent protein and 68 per cent TDN. The calves on the experimental group started getting calf starter on the eighth day onwards and the milk was completely withdrawn at the beginning of the fifth week of age. The calves of the control group were fed with concentrates at the beginning of the fifth week when the quantity of the milk was reduced. At 12 weeks of age milk was completely withdrawn. The feeding trial was a period of 24 weeks from the birth of the calves. The statistical analyses of the data collected revealed that the growth rate of calves fed calf starter I was significantly higher as compared to the calves fed calf starter II. But the growth rate of calves in Groups I and II was almost the same. The total gain in body weight was 44.17 kg in a period of 24 weeks for the calves getting calf starter I as compared to the value of 43.08 and 30.91 for groups I and III respectively. Eventhough there was no significant difference with regard to other body measurements in the three groups, the calves that received calf starter I had a higher paunch girth in comparison to the calves on calf starter II. The physiological status of the calves in all the groups as revealed by the study of the blood value was normal and satisfactory. Eventhough all the calves showed a positive nitrogen balance at the termination of the experiment the valves fed calf starter I had a greater nitrogen balance. Calf starter I was found to be beneficial in terms of general condition, physiological status and weight gain of the calves. By incorporating calf starter I in the feeding schedule of calves, a quantity of 141.4 kg whole milk could be made available for human consumption in addition to a saving of Rs. 186.83 in the cost of feeding a calf during the first 24 weeks of age.