Little millet (Panicum sumatrense Roth. ex. Roem. and Schultz.) is an important indigenous small millets crop. The nutritional quality of little millet grain is superior to major cereals. The present experiment was carried out to identify the sources of zinc, iron and calcium rich genotypes. within this objectives 30 selected high yielding genotypes comprising of 26 germplasm accessions and four check varieties viz., CO2, CO3, CO (Samai) 4 and OLM 203 were evaluated in a Randomized Complete Block Design (RCBD) with three replications during summer, 2013 (Jan-May) at Millets Breeding Station, Tamil Nadu Agricultural University, Coimbatore. All the 30 genotypes were subjected for grain nutrient analysis (zinc, iron and calcium) using Atomic Absorption Spectrophotometer. Nutrient analysis results revealed that zinc, iron and calcium contents in dehusked grains of little millet genotypes differed significantly among the genotypes. The zinc content was varied from 2.04 to 8.00 mg/g with a mean of 5.23 mg/g. Wide variation in iron content was observed and it ranged from 1.49 to 23.38 mg/g with a mean of 4.95 mg/g. The grain calcium content ranged from 1.14 to 13.15 mg/g with a mean of 3.90 mg/g. The genotypes TNPsu 25 (8.00 mg/g), TNPsu 23 (7.42 mg/g), TNPsu 21(6.95 mg/g) and TNPsu 9 (6.85 mg/g) had higher zinc content. Similarly the accessions TNPsu 23 (23.38 mg/g) and TNPsu 22 (19.22 mg/g) were superior in grain iron content. The CO3 (13.15 mg/g), CO2 (8.45 mg/g), TNPsu 141 (8.23 mg/g) and CO2 (Samai) 4 (6.52 mg/g) were some of the accessions which had significantly higher calcium content when compared to standard check varieties. A few of the genotypes like TNPsu 25, TNPsu 23 and TNPsu 22 were rich in zinc and iron contents and TNPsu 141 was rich in zinc and calcium contents.
[1]
K. Sahrawat,et al.
Genetic diversity for grain nutrients contents in a core collection of finger millet (Eleusine coracana (L.) Gaertn.) germplasm
,
2011,
Field Crops Research.
[2]
W. Pfeiffer,et al.
HarvestPlus: Breeding Crops for Better Nutrition
,
2007
.
[3]
D. Greenwood,et al.
Dietary fibre and risk of breast cancer in the UK Women's Cohort Study.
,
2007,
International journal of epidemiology.
[4]
Ross M. Welch,et al.
Breeding for micronutrients in staple food crops from a human nutrition perspective.
,
2004,
Journal of experimental botany.
[5]
B. S. Dwivedi,et al.
Manual on Soil Plant and Water Analysis
,
2013
.
[6]
P. Eganathan,et al.
Proximate and Mineral Composition Analysis of Little Millet Collected from Some Millet Growing Areas in Tamil Nadu
,
2012
.
[7]
R. Jain,et al.
Genetic diversity for iron and zinc contents in a collection of 220 rice (Oryza sativa L.) genotypes
,
2011
.
[8]
A. G. Shankar,et al.
Micronutrient composition, antinutritional factors and bioaccessibility of iron in different finger millet (Eleusine coracana) genotypes
,
2007
.
[9]
Wiesmann,et al.
5th report on the world nutrition situation. Nutrition for improved development outcomes.
,
2004
.
[10]
A. Prasad.
Clinical Spectrum of Human Zinc Deficiency
,
1993
.
[11]
B. Zarcinas,et al.
Nitric acid digestion and multi‐element analysis of plant material by inductively coupled plasma spectrometry
,
1987
.