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Assam Agricultural University, Jorhat

Assam Agricultural University is the first institution of its kind in the whole of North-Eastern Region of India. The main goal of this institution is to produce globally competitive human resources in farm sectorand to carry out research in both conventional and frontier areas for production optimization as well as to disseminate the generated technologies as public good for benefitting the food growers/produces and traders involved in the sector while emphasizing on sustainability, equity and overall food security at household level. Genesis of AAU - The embryo of the agricultural research in the state of Assam was formed as early as 1897 with the establishment of the Upper Shillong Experimental Farm (now in Meghalaya) just after about a decade of creation of the agricultural department in 1882. However, the seeds of agricultural research in today’s Assam were sown in the dawn of the twentieth century with the establishment of two Rice Experimental Stations, one at Karimganj in Barak valley in 1913 and the other at Titabor in Brahmaputra valley in 1923. Subsequent to these research stations, a number of research stations were established to conduct research on important crops, more specifically, jute, pulses, oilseeds etc. The Assam Agricultural University was established on April 1, 1969 under The Assam Agricultural University Act, 1968’ with the mandate of imparting farm education, conduct research in agriculture and allied sciences and to effectively disseminate technologies so generated. Before establishment of the University, there were altogether 17 research schemes/projects in the state under the Department of Agriculture. By July 1973, all the research projects and 10 experimental farms were transferred by the Government of Assam to the AAU which already inherited the College of Agriculture and its farm at Barbheta, Jorhat and College of Veterinary Sciences at Khanapara, Guwahati. Subsequently, College of Community Science at Jorhat (1969), College of Fisheries at Raha (1988), Biswanath College of Agriculture at Biswanath Chariali (1988) and Lakhimpur College of Veterinary Science at Joyhing, North Lakhimpur (1988) were established. Presently, the University has three more colleges under its jurisdiction, viz., Sarat Chandra Singha College of Agriculture, Chapar, College of Horticulture, Nalbari & College of Sericulture, Titabar. Similarly, few more regional research stations at Shillongani, Diphu, Gossaigaon, Lakhimpur; and commodity research stations at Kahikuchi, Buralikson, Tinsukia, Kharua, Burnihat and Mandira were added to generate location and crop specific agricultural production packages.

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  • ThesisItemOpen Access
    EVALUATION OF FUNCTIONAL PROPERTIES OF SEEDS FROM MORINGA OLEIFERA AVAILABLE IN ASSAM
    (2023) HOQUE, FARHANAZ SULTANA; Baruah, Luna Dutta
    The present study entitled “Evaluation of functional properties of seeds from Moringa Oleifera available in Assam” was undertaken with an aim to evaluate the functional properties of the Moringa oleiufera seeds.The objectives of the study were ,analysis of phytochemical and antioxidant properties of Moringa oleifera seeds, formulation of Moringa oleifera seeds flour incorporated product, nutritional evaluation of the developed product and analysis of hypoglycemic efficacy of the developed product. In the present study, a total no. of 45 different formulations of product (chapatti) were developed with incorporation of raw and debittered Moringa oleifera seeds flour. The debittering treatments were boiling, roasting as well as soaking ( for 12, 24, 36 and 48 hrs.) and boiling, and soaking (for 12, 24, 36 and 48 hrs.) and roasting. Results obtained from the analysis of phytochemical and antioxidant properties of the raw and treated Moringa oleifera seeds available in Assam in terms of total phenolic contents (mg/100g) of Moringa oleifera seeds for T0, TB, TSBa, TSBb, TSBc, TSBd, TR, TSRa, TSRb, TSRc, TSRd were found to be 29.55±0.01 mg/100g, 23.87±0.01 mg/100 g, 19.28±0.007 mg/100g, 18.96±0.02 mg/100g, 17.87±0.02 mg/100g, 16.26±0.02 mg/10g, 24.57±0.01 mg/100g, 19.55±0.04 mg/100g, 19.95±0.58 mg/100g, 19.99±0.017 mg/100g, 20.00±0.02 mg/100 g respectively. Total flavanoid contents (mg/100g) of Moringa oleifera seeds for T0, TB, TSBa, TSBb, TSBc, TSBd, TR, TSRa, TSRb, TSRc, TSRd, were found to be 5.82±0.04 mg/100g, 9.07±0.01 mg/100g, 6.03±0.02 mg/100g, 5.76±0.02 mg/100g, 5.73±0.01 mg/100g, 5.66±0.02 mg/100g, 5.74±0.01 mg/100g, 5.65±0.04 mg/100g, 5.62±0.03 mg/100g, 5.60±0.02 mg/100g respectively whereas tannin content (mg/100g) of the raw and treated Moringa oleifera seeds for T0, TB, TSBa, TSBb, TSBc, TSBd, TR, TSRa, TSRb, TSRc, TSRd; were 6.11±0.08 mg/100g, 3.24±0.01 mg/100g, 2.52±0.02 mg/100 g, 2.82±0.01 mg/ 100 g, 2.77±0.04 mg/100g, 2.92±0.01 mg/100 g, 3.02±0.02 mg/ 100 g, 2.89±0.05 mg/ 100g, 2.82±0.01 mg/ 100 g, 2.80±0.01 mg/100g, 2.69±0.01 mg/ 100g, respectively. The phytic acid contents of the raw and treated Moringa oleifera seeds ranged from 7.51±0.02 mg/ 100 to 9.82±0.03 mg/100g. The phytate contents (mg/100g) of the raw and treated Moringa oleifera seeds were observed as 8.05±0.03 mg/100g, 7.75±0.03 mg/100g, 7.51±0.02 mg/100 g, 7.54±0.01 mg/ 100 g, 7.57±0.01 mg/100g, 7.62±0.03 mg/100 g, 9.82±0.03 mg/ 100 g, 7.74±0.03 mg/ 100g, 7.77±0.01 mg/ 100 g, 7.84±0.02 mg/100g, 7.90±0.02 mg/ 100g, in T0, TB, TSBa, TSBb, TSBc; TSBd, TR, TSRa, TSRb, TSRc, TSRd; respectively. Antioxidant activity was ovserved highest in boiled Moringa oleifera seeds which showed 71.18±0.06%. All the formulations of raw and treated Moringa oleifera seeds flour incorporated chapatti with the level of 5 to 20 per cent were subjected to sensory evaluation by 10 semi trained panelists using 9 point hedonic scale. From the sensory evaluation chapatti incorporated with 20 per cent soaked (12 hrs) and boiled Moringa oleifera seeds flour i.e. CSBa4 and chapatti incorporated with 15 percent soaked (12 hrs) and roasted Moringa oleifera seeds flour i.e. CSRa3 were highly accepted in terms of all the sensory attributes and selected for further analysis. Results revealed in terms of moisture, crude fibre, crude fat, crude protein, total carbohydrate, total energy content and total mineral content for CSBa4 and CSRa3 were : 32.82±0.68 g/100g and 24.21±0.38 g/100g; 3.25±0.03 g/100g and 3.75±0.04 g/100g; 3.58±0.02 g/100g and 4.25±0.03 g/100g; 8.57±0.02 g/100g and 7.23±0.04 g/100g; 30.00±0.02 and 35.00±0.01; 214.09±0.04 kcal/100g and 220.43±0.03 kcal/100g; 1.80±0.03 g/100g and 1.89±0.01 g/100g respectively. Mineral contents of the developed product in terms of iron, calcium, potassium and zinc were found to be 4.07±0.04 mg/100g and 6.73±0.10 mg/100g; 40.16±0.42 mg/100g and 38.42±0.52 mg/100g; 158.6±1.00 mg/100g and 117.4±0.01 mg/100g; 1.10±0.02 mg/100g and 1.11±0.03 mg/100g respectively. In vivo studies were performed to study the impact of supplementation of the developed product in Wister rats. The product obtained score of 45.65 in the glycemic index scale and it can be considered as low glycemic index food. It also significantly reduced the blood glucose level of alloxan induced diabetic rats in 21 days supplementation period with @100 mg/kg b.w, @300 mg/kg. b.w. and @900 mg/ b.w. in dose dependent manner. The mean decrease in blood glucose levels were found to be 25 mg/dl followed by 21 mg/dl and 19 mg/dl in group D3, group D2 and group D1 respectively. From the findings of the study it can concluded that Moringa oleifera seeds possesed a decent nutritional composition and it can be incorporated in value added product development after subjecting to debittering treatments. The developed product can also be commercialized and popularized among different populations as a source of nutri dense food as this has low glycemic index property (45.65) and antihyperglycemic effect. It can be recommended to patients having type 2 diabetes mellitus with some modifications, as well as for people with other non communicable diseases.
  • ThesisItemOpen Access
    EFFECT OF PROCESSING ON IN-VITRO STARCH DIGESTIBILITY AND GLYCEMIC INDEX OF SELECTED RICE VARIETIES OF ASSAM
    (AAU, Jorhat, 2019-07) Devi, Laishram Maria; Das, Pranati
    Rice is one of the most widely consumed staple foods, especially in Asia. It accounts for 20 per cent of the world’s dietary energy supply. As a major component of rice, starch plays an important role in human nutrition, and consequently its characterisation in rice variants is of high nutritional importance. To this, the present study estimated the in-vitro starch digestibility (resistant starch (RS), non-resistant starch (NRS) and total starch (TS)), available starch (AS), hydrolysis index (HI) and in-vitro glycemic index (GI) of different processing techniques. Ten red kernel rice varieties of Assam were analyzed for the effect of both raw rice flour and freshly cooked rice in dehusked rice and 6 per cent degree of polishing. Dehusked and polished rice yield were 68.33±0.38 to 75.23±0.19 per cent and 64.14±0.13 to 73.67±0.29 per cent, respectively. Head rice yield (HRY) and broken rice yield (BRY) of the dehusked rice varieties were 54.03±0.34 to 74.34±0.05 per cent and 0.68±0.06 to 14.55±0.32 per cent, respectively. Polishing of rice grains decreased HRY (41.76±0.40 to 68.39±0.09%) but increased BRY (2.05± 0.11 to 22.52±0.41%). The dehusked samples had 17.64±0.11 to 19.17±0.04 g/100 g of RS, 61.19±0.07 to 66.28±0.19 g/100g of NRS and 80.01±0.11 to 85.02±0.20 g/100g of TS. Resistant starch decreased significantly (p≤0.05) on polishing as well as cooking, while NRS and TS increased significantly (p≤0.05) in polishing. However, TS decreased on cooking. Available starch, hydrolysis index and glycemic index of the dehusked rice samples were in the range of 51.80±0.14 to 89.57±0.51 per cent, 3.37±0.02 to 14.67±0.03 per cent and 41.91±0.03 to 50.99±0.11 per cent, respectively. Polishing of the rice samples showed no significant (p≥0.05) change in AS, HI and GI. Cooking significantly reduced AS, whereas HI and GI content increased significantly (p≤0.05) upon cooking. Therefore, polishing and cooking of rice grains had significant effect on the in-vitro starch digestibility and GI. In addition, varieties of Jul and Kaoi Jamfri had comparatively higher RS and lower GI, and thus can be recommended for popularization. Also, further research can be extended for analyzing the effect of degree of polishing and different cooking methods on starch digestibility and GI. Such nutritionally distinguished rice varieties could be used to develop rice based products and supplementary food mixes which have therapeutic values.
  • ThesisItemOpen Access
    EFFECT OF PROCESSING ON NUTRIENT COMPOSITION AND BIOACTIVE COMPONENTS OF SELECTED RICE VARIETIES OF ASSAM
    (AAU, Jorhat, 2019-07) Gogoi, Senorita; Das, Pranati
    A study was carried out with the objective to determine the effect of processing on physico- chemical properties and bioactive compounds of selected red rice varieties of Assam. Seven red pigmented rice varieties were selected and procured from Krishi Vigyan Kendra, Silapathar, Dhemaji. A series of laboratory tests were performed on both the uncooked and cooked forms of dehusked and 6 per cent polished rice samples to find out the physico- chemical properties, mineral content and the bio- active compounds. The dehusked and polished rice yield of the selected red rice varieties was found to be in the range of 68.33±0.52 to 75.23±0.47 per cent and 64.14±0.39 to 73.67±0.69 per cent, respectively. Head rice yield (HRY) and broken rice yield (BRY) of the varieties ranged from 55.13±0.99 to 73.93±0.73 per cent and 0.93±0.16 to 13.60±0.58 per cent, respectively and polishing of the rice grains decreased HRY (40.82±1.12 to 67.44±1.23 per cent) but increased the BRY (2.96± 0.19 to 23.15±1.06 per cent). Length, breadth, thickness and length/breadth ratio of the dehusked rice samples ranged from 5.00±0.33 to 5.90±0.32 mm, 2.10±0.21 to 2.75±0.35 mm, 1.59±0.14 to 2.03±0.02 mm and 1.89±0.40 to 2.85±0.36, respectively. Thousand grain weight, volume and bulk density ranged from 13.46±0.00 to 19.40±0.00 g, 16.67±0.29 to 25.83±0.29 ml and 0.69±0.01 to 0.88±0.01 g/ml in the dehusked samples. The length, breadth, thickness, thousand grain weight and thousand grain volume of rice varieties significantly (p≤0.05) reduced on polishing, whereas the length/ breadth ratio and bulk density increased. Water absorption capacity (WAC), cooking time and grain elongation ratio of the dehusked rice samples ranged from 2.06±0.16 to 2.77±0.21 ml/g, 21.66±1.53 min. to 38.33±1.15 min. and 0.98±0.01 to 1.14±0.02. Water absorption capacity and grain elongation ratio significantly (p≤0.05) increased whereas the CT decreased significantly (p≤0.05) on polishing. The dehusked samples had 11.64±0.08 to 12.75± 0.04 g/100 g of moisture, 9.31±0.00 to 13.50± 0.66 g/100 g of crude protein, 2.53± 0.09 to 3.71±0.04 g/100 g of crude fat, 0.56±0.01 to 0.81±0.03 g/100 g of crude fibre, 1.24±0.01 to 2.60±0.03 g/100 g of total ash, 68.60±1.44 to 73.87±0.18 g/100 g of carbohydrate and 352.99±0.80 to 361.86±2.78 kcal/100 g of energy. The crude protein, crude fat, crude fibre and total ash content decreased significantly (p≤0.05) on polishing as well as cooking. The carbohydrate content significantly (p≤0.05) increased on polishing as well as cooking. The dehusked samples had iron, zinc, calcium, phosphorus and magnesium content in the range of 4.47±0.18 to 12.46±0.63 mg/100g, 1.41±0.11 to 2.93±0.05 mg/100 g, 9.96±0.11 to 37.73±0.58 mg/100g, 134.54±3.44 to 221.57±3.48 mg/100 g and 0.13±0.01 to 1.21±0.00 mg/100 g, respectively. Polishing significantly (p≤0.05) reduced the iron, zinc, calcium, phosphorus and magnesium content. Cooking of the rice samples showed no significant (p≥0.05) change in the iron, zinc, calcium content on cooking, while magnesium content reduced significantly (p≤0.05). No significant (p≥0.05) change in phosphorus content was seen in the dehusked samples, whereas the polished samples showed significant (p≤0.05) loss of phosphorus upon cooking. The bioactive compounds were determined in terms of total antioxidant capacity (TOA), total anthocyanin content (TAC), total phenolic content (TPC), total flavonoid content (TFC) and total carotenoid content (TCC) and were observed to significantly (p≤0.05) decreased on polishing as well as cooking. The TOA, TAC, TPC, TFC and TCC of the dehusked samples ranged from of 44.67±0.45 to 81.08±0.45 per cent, 11.35±0.45 to 23.71±0.94 mg/100 g, 46.13±0.88 to 109.50±0.64 mg GAE/100 g, 12.24±1.19 to 39.23±1.59 mg QE/100 g and 0.42±0.02 to 1.85±0.07 μg/100 g, respectively. The present study provides the evidence that polishing and cooking of the rice grains has significant effect on the physical and nutrient quality of the rice varieties. The variety Kaoi Jamfri showed better mineral content and antioxidant capacity than rest of the varieties and can be recommended for popularization among rural and urban population. Further studies may be taken out to find out the degree of polishing at which maximum milling recovery and retention of nutrient takes place. The rice varieties may be used to formulate supplementary food mixes, develop rice based products. The unpolished rice varieties may be recommended for consumption to prevent nutrient deficiencies among the people. Further studies can be taken out to study the use of the rice bran to formulate functional food.