Why Doesn’t Honey Spoil? – The Chemistry of Honey
Honey is something of an oddity, in that, unlike most foods, it
doesn’t spoil over time. In fact, the oldest known sample of honey,
found in an Ancient Egyptian tomb and dated to approximately 3000 years
ago, was still perfectly edible. What is it, then, that gives honey
this unusual property?
To answer this question, we need to understand how bees make honey in
the first place. Honey derives from plant nectar, which is a mix of
various different sugars, proteins, and other compounds, in a water
solution. Whilst nectar composition varies from plant to plant, and a
range of chemical compounds are commonly present, often the dominant
sugar is sucrose. This is actually exactly the same sugar as is found in
your kitchen, as table sugar. The varying concentrations of the
different components of nectar in different nectars is the reason that a
range of types of honey are available, depending on which type of
nectar the bees have predominantly been collecting.
Bees are the key intermediate step between nectar and honey. Worker
bees will collect the nectar from flowers, and store it in their honey
stomach – distinct from their normal stomach. Enzymes secreted from
glands are then mixed with the nectar; these enzymes begin the breakdown
of the sucrose in the nectar to simpler sugars. Sucrose is what we
refer to as a disaccharide; it actually consists of two different
simpler sugars, glucose and fructose, joined together. In the bee’s
honey stomach, the sucrose molecules are gradually split by the enzymes
into glucose and fructose.
Glucose and fructose can also be referred to as dextrose and levulose respectively. These two sugars are actually structural isomers, as they have the same chemical formula. The names ‘dextrose’ and ‘levulose’ refer to their effect on plane-polarised light. Due to the difference in the arrangement of the atoms, dextrose rotates plane-polarised light to the right, whilst levulose rotates it to the left. The prefixes ‘dextro-’ and ‘levulo-’ come from the latin for right and left respectively.
Once the worker bee returns to the hive, it will regurgitate the
nectar solution and pass it on to one of the house bees, who remain in
the hive. The house bee will continue the process the worker bee started
– for up to 20 minutes, it will regurgitate and re-drink the nectar,
continuing to mix it with enzymes and breaking it down further. Whilst
some sucrose will remain, the majority is broken down into glucose and
fructose.
Once suitable breakdown has been achieved, the house bee deposits the
nectar into the honeycomb in the hive. Then another important step in
the process begins. Nectar can be up to 70% water, and this water must
be evaporated in order to produce the consistency of honey that we’re
all familiar with. The bees achieve this by fanning the honeycomb with
their wings in order to encourage rapid evaporation of the water from
the nectar mixture. Eventually, the water content of the solution will
drop to around 17%, vastly reduced from the content of the original
nectar. The conversion of the watery nectar to syrupy honey takes
between 1-3 days.
The water content of honey is a key
factor in why it doesn’t spoil. At 17%, its water content is much lower
than that of bacteria or fungi. Honey also has a low water activity;
this is a measure of the amount of water in a substance that is
available to support microbial growth. Water activity is on a scale of 0
to 1, with most moulds and bacteria being unable to grow under a water
activity of 0.75. Honey has a water activity of 0.6. This, combined with
the fact that its low water content dehydrates bacteria, makes it
resistant to spoiling.
Another factor that helps honey avoid spoiling is its acidity. Its
average pH is around 4; this acidity is contributed to by a number of
acids, including formic acid and citric acid, but the dominant acid is
gluconic acid, produced by the action of bee enzymes on some of the
glucose molecules in the honey. This further boosts honey’s
antibacterial properties, as many bacteria thrive in neutral rather than
acidic conditions. Hydrogen peroxide is also produce by the production
of gluconic acid – this too can inhibit the growth of bacteria. Honey’s
antibacterial properties are actually potent enough for it to be
effective as an impromptu wound dressing.
On a final note, you might also notice that, over time, honey tends
to crystallise and solidify. Because honey’s water content is so low, it
can be considered to be a super-saturated solution of the various
sugars; a solution is considered saturated when as much solid as is
possible has been dissolved in it. Over time, glucose will precipitate
out of the solution, forming solid crystals. The honey is still
perfectly fine to eat, and this doesn’t constitute spoilage – to revert
it back to its liquid form, all that’s required is immersion in warm
water for a few minutes.
Font: Spiral Horn Apiary
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