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  • Starch gelatinization is a process of breaking down the intermolecular bonds

  • of starch molecules in the presence of water and heat, allowing the hydrogen

  • bonding sites to engage more water. This irreversibly dissolves the starch

  • granule in water. Water acts as a plasticizer.

  • Three main processes happen to the starch granule: granule swelling,

  • crystal or double helical melting, and amylose leaching.

  • During heating, water is first absorbed in the amorphous space of starch, which

  • leads to a swelling phenomenon. Water then enters via amorphous regions

  • the tightly bound areas of double helical structures of amylopectin. At

  • ambient temperatures these crystalline regions do not allow water to enter.

  • Heat causes such regions to become diffuse, the amylose chains begin to

  • dissolve, to separate into an amorphous form and the number and size of

  • crystalline regions decreases. Under the microscope in polarized light starch

  • loses its birefringence and its extinction cross.

  • Penetration of water thus increases the randomness in the starch granule

  • structure, and causes swelling, eventually soluble amylose molecules

  • leach into the surrounding water and the granule structure disintegrates.

  • The gelatinization temperature of starch depends upon plant type and the amount

  • of water present, pH, types and concentration of salt, sugar, fat and

  • protein in the recipe, as well as starch derivatisation technology used. Some

  • types of unmodified native starches start swelling at 55 °C, other types at

  • 85 °C. The gelatinization temperature of modified starch depends on for example

  • on the degree of cross-linking of the amylopectin, the degree of acid

  • treatment, acetylation. Gel temperature can also be modified by genetic

  • manipulation of starch synthase genes. Gelatinization temperature also depends

  • on the amount of damaged starch granules. These will swell faster.

  • Damaged starch can be produced, for example, during the wheat milling

  • process, or when drying the starch cake in the starch plant. There is an inverse

  • correlation between gelatinization temperature and glycemic index.

  • Gelatinization improves the availability of starch for amylase hydrolysis. So

  • gelatinisation of starch is used constantly in cooking to make the starch

  • digestable or to thicken/bind water in roux sauce, a soup.

  • Retrogradation Cooked, unmodified starch, when cooled

  • for a long enough period, will thicken and rearrange itself again to a more

  • crystalline structure; this process is called retrogradation. During cooling,

  • starch molecules gradually aggregate to form a gel. Molecular associations

  • occur: Amylose-Amylose ; Amylose-Amylopectin;

  • Amylopectin-Amylopectin. A mild association amongst chains come together

  • with water still embedded in the molecule. Due to the tightly packed

  • organization of small granule starches, retrogradation occurs much more slowly

  • compared to larger starch granules. High amylose starches require more energy to

  • break up bonds to gelatinize into starch molecules, leading to a rigid and stiff

  • gel. A mild association amongst chains come together with water still embedded

  • in the molecule. Due to strong associations of hydrogen

  • bonding, longer amylose molecules will form a stiff gel. Amylopectin molecules

  • with longer branched structure, increases the tendency to form strong

  • gels. Granule size do not directly impact starch performance, but it is one

  • of the main factors affecting starch gelatinzation and retrogradation. High

  • amylopectin starches will have a stable gel, but will be softer than high

  • amylose gels. Retrogradation restricts the

  • availability for amylase hydrolysis to occur.

  • Pregelatinized starch Pregelatinized starch is starch cooked

  • and then dried in the starch factory on a drum dryer or in an extruder making

  • the starch cold-water-soluble. Also spray dryers are used to obtain dry

  • starch sugars and low viscous pregelatinized starch powder.

  • Determination A simple technique to study starch

  • gelation is by using a Brabender Viscoamylograph. It is a common

  • technique used by food industries to determine the pasting temperature,

  • swelling capacity, shear/thermal stability and the extent of

  • retrogradation. Under controlled conditions, starch and distilled water

  • is heated at a constant heating rate in a rotating bowl and then cooled down.

  • The viscosity of the mixture deflects a measuring sensor in the bowl. This

  • deflection is measured as viscosity in torque over time vs. temperature, and

  • recorded on the computer. The viscoamylograph provides the audience

  • with the beginning of gelatinization, gelatinization maximum, gelatinization

  • temperature, viscosity during holding, and viscosity at the end of cooling.

  • DSC or Differential scanning calorimetry is another methods industries use to

  • examine properties of gelatinized starch. As water is heated with starch

  • granules, gelatinization occurs, involving an endothermic reaction.

  • The initiation of gelatinization is called the T-onset. T-peak is the

  • position where the endothermic reaction occurs at the maximum. T-conclusion is

  • when all the starch granules are fully gelatinized, and the curve remains

  • stable. See also

  • Dextrin Modified starch

  • Starch References

  • External links Food Resource, Starch, Oregon State

  • University Corn starch gelatinization, filmed with

  • microscope, Youtube

Starch gelatinization is a process of breaking down the intermolecular bonds

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