Article

Rate of digestion

Digestion of food involves chemical reactions that break up large food molecules into their ‘building block’ components. There are a number of factors that affect the rates of these reactions.

Surface area

Chewing breaks the large into the small. The mechanical digestion of food in the mouth involves converting bite-sized pieces of food into smaller particles. This has the effect of increasing the surface area of the food particles and allowing saliva to be thoroughly mixed with them.

Saliva is a watery fluid containing a slippery substance called mucin, which lubricates the food for easier swallowing, as well as a starch-digesting enzyme called amylase. When chewed, any starch present in the food is then readily exposed to amylase, speeding up the digestion process.

Surface area increases as particle size decreases for a given bite-sized piece of food:

Diagram of surface area increases as particle size decreases

Cubes of food

The diagram illustrates how surface area increases as particle size decreases for a given bite-sized piece of food. Although the particles in 3 are smaller than in 1, the total surface area available is nearly 3 times larger.

Rights: The University of Waikato Te Whare Wānanga o Waikato
  • If a cube of food has 1 cm sides, the surface area of 1 face is 1 x 1 cm = 1 cm2 and the total surface area of the cube = 6 x 1 cm2 = 6 cm2.

  • If the cube of food is divided into 8 cubes with 0.5 cm sides, the total surface area of 1 cube is 6 x 0.5 x 0.5 cm2 = 1.5 cm2, and the total surface area of 8 cubes is 8 x 1.5 cm2 = 12 cm2.

  • If the cube of food is divided into 27 cubes with 0.33 cm sides, the total surface area of 1 cube is 6 x 0.33 x 0.33 cm2 = 0.6534 cm2, and the total surface area of 27 cubes is 27 x 0.6534 cm2 = 17.64 cm2.

Surface area is a key factor in determining the rate of a chemical reaction, so to aid digestion, food should be thoroughly chewed before swallowing.

Temperature

Most chemical reactions proceed at a faster rate as temperature increases. Food digestion reactions follow this general principle, but there is an upper temperature limit of about 40°C.

Graph indicates how the rate of digestion of starch

Rate of reaction and temperature

The graph indicates how the rate of digestion of starch using saliva changes as temperature changes.

Rights: Dr Huw Parry http://creativecommons.org
Denatured enzyme diagram change from heat.

Denatured enzyme

The enzyme is a protein, and at high temperatures, the shape of the protein is altered, preventing it from performing its function. It has been denatured.

Above 40°C, the enzyme present in saliva and responsible for the digestion of starch is deactivated. The enzyme is a protein, and at high temperatures, the shape of the protein is altered preventing it from performing its function. It has been denatured.

pH

The rates of chemical digestion processes involving enzymes are dependent on the pH of the surrounding fluids.

pH is a measure of the acidity or basicity of a given solution. The scale covers the range 1–14, with pH 7 being neutral, pH 1–6 acidic and pH 8–14 basic.

Graph showing activity of amylase changes as the pH changes.

Enzyme activity and pH

The activity of amylase changes as the pH changes. A higher enzyme activity will result in a faster rate of reaction. Other digestive enzymes have a similarly shaped graph but with the peak either as shown or displaced to the left (acidic optimum) or to the right (basic optimum).

Rights: The University of Waikato Te Whare Wānanga o Waikato

The enzyme amylase, which is present in saliva, has its maximum activity at pH 7. The activity of amylase changes as the pH changes – a higher enzyme activity will result in a faster rate of reaction.

Enzymes are globular proteins with a characteristic shape. This shape can alter with changing pH, the result being a decrease in activity.

Related content

The article Catalysing chemical reactions with enzymes includes an animated video outlining in detail how enzymes work.

Published: 13 July 2011