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This article has been withdrawn as it was published elsewhere and accidentally duplicated. The original article can be seen here: 10.1108/00070700910941444. When citing the article, please cite: Antu Grewal, Sudesh Jood, (2009), “Chemical composition and digestibility (in vitro) of green gram as affected by processing and cooking methods”, British Food Journal, Vol. 111 Iss: 3, pp. 235 - 242.

Digestibility of pulses is affected due to presence of antinutritional and toxic compounds. Various processing treatments are known to destroy heat labile toxic compounds and other enzyme inhibitors, hence, to improve the texture, palatability and nutritive value of pulses. This paper, therefore, aims to focus on improving the digestibility and availability of nutrients of green gram (Vigna radiata L.) through processing treatments.

The present study was undertaken to see the effect of common processing and cooking treatments on newly released green gram cultivars. To achieve this objective, green gram seeds were soaked in plain water (1:4 w/v) for 12 hours at 37°C. One portion of the soaked seeds was dried at 55°C and left‐over soaked seeds were divided into three portions. One portion of the soaked seeds was dehulled manually. The second portion of the soaked seeds was ordinary and pressure‐cooked (water two times the weight of soaked seeds) for 35 minutes at 95‐100°C and at 1.05 kg/cm² pressure for 15 minutes, respectively. The third portion of the soaked seeds was sprouted for 24 hours at 37°C. All the processed seeds were dried at 55°C in a hot air oven and then ground in a cyclone sample mill and stored for estimation of nutritional parameters using standard methods.

Soaking and cooking treatments had no significant effect on proximate composition, whereas sugar contents increased and starch contents decreased significantly. Soaking and cooking treatments also improved in vitro starch digestibility significantly. De‐hulling of soaked seeds further improved starch digestibility and also caused significant change in protein, fat, ash, crude fibre and sugar contents. Germination decreased starch, thereby raising the level of the soluble sugars and improved starch digestibility by 49 and 48 percent, respectively, in both cultivars. Similarly, pressure‐cooking also increased starch digestibility by about 44 and 49 percent, respectively, in both cultivars. Cooking may gelatinize starch and germination may mobilize starch, resulting in improved digestibility of starch by α‐amylase.

Evolving high‐yielding crop varieties is one of the most important strategies to fill the gap between demand and supply of food legumes and also to improve the nutritional status of the population consuming such foods. Hence, it is imperative to judge their chemical composition and improve them through inexpensive processing techniques.

The paper gives an overall view of nutritive values of new and traditional varieties of vegetables and will be of value to those who supply the consumer.

Probiotic fermented foods are fast being recognized as health foods. Most of such foods are based on dairy products but little research work is available on coarse cereals and millets, which constitute the staple foods in developing countries. This paper aims to determine the effect of germination and fementation on nutrient composition of pearl millet based food blends.

Indigenously developed pearl millet based food blends containing raw and germinated pearl millet flour, whey powder and tomato pulp (2:1:1w/w) were autoclaved, cooled and fermented with 5 percent Lactobacillus acidophilus curd which supplied 10⁶cells/ml to the slurry at 37°C for 12 h. The unfermented blends, after autoclaving, served as controls. The developed food blends were subjected to nutritional evaluation by using the standard methods of analysis. The data were statistically analysed.

Pearl millet based, germinated, autoclaved and fermented, food blend maintained adequate cell viability (8.64 cfu g^‐1) as compared to non‐germinated food blend. Germination and probiotic fermentation caused significant improvement in the contents of thiamine, niacin, total lysine, protein fractions, sugars, soluble dietary fibre and in vitro availability of Ca, Fe and Zn of food blends.

Research is currently aimed at developing probiotic millet based food mixture, which had enhanced nutrient profile. Hence, it can be considered for commercialization after establishing its health/therapeutic implications among the population.

Dairy foods have preferentially been used as the carrier medium for probiotics. This paper explores the possibility of using staple foods as the carrier medium. The consumption of such food mixtures containing viable probiotic bacteria should be enhanced among consumers in term of their role in health maintenance and disease prevention.

Wheat is considered nutritionally poor, due to deficiency of essential amino acids such as lysine and threonine, whereas fenugreek (Trigonella faenum graecum L.) flour has a high protein content (25 per cent), lysins (5.7g/16gN), soluble (20 per cent) and insoluble (28 per cent) dietary fibre besides being rich in calcium, iron and beta‐carotene. Fenugreek seeds contain 20 per cent soluble fibre (gum), which can act as functional agent in wheat dough. The presence of bitter saponins in fenugreek seeds limits their acceptability in foods. However, it has been possible to debitter fenugreek seeds by using various domestic processing methods. Therefore, their use can be exploited as functional and nutritional food as well as therapeutic agents. Hence, in the present study efforts have been made to develop wheat‐fenugreek‐based health bread.

In commonly grown varieties of wheat, namely WH‐423, and fenugreek namely Pusa, early bunching was obtained. Fenugreek seeds were divided into three portions. One portion was left unprocessed (raw), while the other two portions were soaked (12hr at 37^○C) and germinated (48hr at 37^○C) separately. Soaked and germinated samples were dried at 55‐60^○C. Dried samples of raw, soaked and germinated seeds were ground to fine powder. Fenugreek seed powder (raw, soaked and germinated) was blended separately with wheat flour at different levels, namely 5, 10, 15 and 20 per cent. Breads from control and supplemented flours were baked in replicates. Baking, organoleptic and nutritional characteristics were analysed in the control and supplemented breads. The data were statistically analyzed in complete randomized design for analysis of variance according to the standard method.

Supplementation of wheat flour with fenugreek flour from 5 to 20 per cent levels increased the protein, lysine, minerals and fibre contents of bread. Additions of fenugreek (raw, soaked and germinated) up to the level of 15 per cent produced bread with a satisfactory loaf volume and other sensory quality attributes (crumb colour, crumb texture, taste etc.), whereas the 20 per cent level of supplementation caused a depression effect in loaf volume and the breads were found to be bitter in taste, However, among the various supplemented breads, germinated fenugreek flour‐supplemented bread at 15 per cent level showed satisfactory baking and organoleptic characteristics and contained an appreciable amount of protein (24 per cent), total lysine (3.02g/100g protein), dietary fibre (12.04 per cent) and minerals.

Fast food are becoming as popular, as in developing countries. Keeping this fact in view, in the present study, health breads were prepared. The developed product had good acceptability, was nutritionally rich and had therapeutic value. So, these can be considered for commercialization.

As fenugreek seeds contain 20 per cent soluble fibre (gum), and 5.7g/16gN lysine contents, the soluble fibre of fenugreek seeds has been reported to reduce blood sugar and cholesterol levels. Therefore, their use can be exploited in the development of health foods.