emulsi pada produk susu. chocolate milk and infant formulae

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Emulsi Pada Produk Susu

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  • Slide 1

Emulsi Pada Produk Susu Slide 2 Slide 3 Chocolate milk and infant formulae Slide 4 Complete nutritional formula Slide 5 Slide 6 Slide 7 Kasein Misel Slide 8 Slide 9 Mengapa susu segar berwarna putih ? Jawab : Susu tersusun dari berbagai nutrien yang terlarut dalam air atau terdispersi sebagai koloid Susu segar bukan hanya merupakan larutan dan dispersi koloid, namun juga merupakan emulsi Warna putih pada susu segar disebabkan oleh koloid dan emulsi komponen susu (lemak dan protein) dalam fase air. Slide 10 Mengapa susu segar berwarna putih ? 1.Protein susu - casein micelles 2.Bentuk, ukuran dan kenampakan misel kasein memberikan warna putih pada susu 3.Perbesaran 37,500x (garis: 1.2 m). Slide 11 Koagulasi Susu Segar The coagulation of milk by chymosin includes two separate steps: proteolysis and aggregation Slide 12 Aggregation behavior of emulsifier molecules (a) Head group larger than the tail: micelle formation in water (b) Cylinder-shaped molecule: formation of parallel bilayers (c) Head group smaller than the tail: formation of inverted micelles, enclosing water. Slide 13 A schematic drawing of a lamellar phase. The emulsifier molecules are arranged in parallel sheets in such way that the hydrophilic head groups of the molecules are in contact with water and that the hydrophobic chains are in contact with each other and excluded from water. Slide 14 Misel Kasein Caseins exist in large spherical collodial micells with calcium phosphate. These micelles comprises 93% (w/w) caseins and range in size from 500 to 3000 A in diameter. The calcium and phosphate play a very important role in maintaining the integrity of the casein mucelles, and are commonly referred to as colloid calcium phosphate. Slide 15 Emulsion formation, structure and stability During homogenisation, fat globules with sub-micron size are formed Milk proteins migrate to the newly formed fat globule surfaces Capability to form a stable emulsion is determined by the ability of the protein to unfold at the fat-water interface Protein load affects the stability of emulsion towards heating and storage Slide 16 Fat globules in recombined milk Natural milk 10 mm Slide 17 Fat globules in recombined milk Natural milk Recombined (homogenized milk) 10 mm Slide 18 Fat Globule Stabilization by Milk Proteins Protein at fat/aqueous interface Slide 19 Emulsion destabilisation in recombined milk Thermodynamically unstable Mechanisms of destabilisation: aggregation, flocculation, coalescence and creaming Slide 20 Flocculation and coalescence Aqueous phase Whey proteins Oil droplet Casein micelle Slide 21 Flocculation and coalescence Aqueous phase Flocculation Whey proteins Oil droplet Casein micelle Slide 22 Flocculation and coalescence Aqueous phase Flocculation Coalescence Whey proteins Oil droplet Casein micelle Slide 23 Consequences of coalescence Coalescence leads to an increase in the rate of separation Oil Water Slide 24 Particle size distribution A stable recombined milk 0 2 4 6 8 10 12 14 16 18 20 Frequency (%) 0.010.1110100 Particle size (um) Slide 25 0 4 8 12 16 20 Volume frequency (%) 0.010.1110100 Particle size (m) Particle size distribution unstable recombined milks Slide 26 Slide 27 Slide 28