Methods to differentiate between cotton tract area ghee and cotton seed oil adulterated ghee.

Ghee, the clarified butter fat is one of the principal dairy products in India. In some places of India, cotton seed is fed extensively to dairy animals which changes the physico-chemical constants and fatty acid profile of the milk fat. Ghee is often adulterated with cotton seed oil and is marketed as cotton tract area ghee. Physico-chemical constants like RM value, Polenske value, BR reading, saponification value, iodine value and colorimetric tests i.e., Halphen and DPPH radical test were employed to differentiate ghee adulterated with cotton seed oil and that from cotton tract area. Chromatographic techniques like HPLC and GC-MS were also explored. Physico-chemical constants were not useful to differentiate the two types of ghee. Cyclopropenoic acids were observed only in ghee adulterated with cotton seed oil and not in cotton tract ghee. The RP-HPLC could able to distinguish the cotton tract area ghee from ghee adulterated with cotton seed oil on the basis of presence of ß-sitosterol in the latter. Halphen test was positive for cotton tract ghee, but not for the cotton seed oil adulterated ghee. Methylene blue reduction and DPPH radical test were also found to be useful to distinguish both types of ghee.

Effect of incorporation of iron-whey protein concentrate (Fe-WPC) conjugate on physicochemical characteristics of dahi (curd).

Dahi samples were prepared from milk incorporated with spray-dried iron-whey protein concentrate (Fe-WPC) conjugate and ferrous sulfate (FeSO4) with three different concentrations of iron i.e. 15, 20 and 25 mg/L and their quality characteristics were determined. Fe-WPC conjugate incorporated dahi showed better sensory, textural and physical attributes as compared with those of FeSO4 fortified and control dahi. Non-significant (p > 0.05) changes were observed in attributes like acidity and flavor, color and appearance, body and texture scores of dahi fortified with Fe-WPC conjugate with upto 20 mg/L iron as compared to those of control. In contrast, definite metallic flavor was perceptible in case of FeSO4 incorporated dahi even at 15 mg/L level. Water holding capacity, viscosity and firmness were significantly (p < 0.05) higher in 20 mg/L Fe-WPC conjugate incorporated dahi samples as compared with those of 20 mg/L FeSO4 incorporated dahi samples. In vitro bio accessibility of iron from Fe-WPC conjugate incorporated dahi was found to be significantly (p < 0.05) higher than that from FeSO4 incorporated dahi. Therefore, the results indicated that Fe-WPC conjugate can be fortified in dahi with upto 20 mg/L without significantly altering its physicochemical properties and with a higher bioaccessibillity of iron.

Construction of a lateral flow strip for detection of soymilk in milk.

A lateral flow based detection method for ascertaining the presence of soymilk in whole bovine milk has been described. The method uses commercially available rabbit anti-soy protein antibodies conjugated to gold nanoparticles (AuNPs) wherein soymilk protein in adulterated milk and soymilk protein at test line competes for limited antibodies. At control line, anti-rabbit immunoglobulin was immobilized for ensuring flow properties of antibody-conjugated AuNPs. Absence or diminished intensity of band at test line indicates presence of soymilk in milk. The soymilk detection limit was 1.75% (v/v) in whole bovine milk and results are available in 5 min. Constructed lateral flow device can be used for on-spot examination of soymilk in milk.