|
By J. W. WHITE, JR. AND LANDIS W.
DONER(1)
BEEKEEPING IN THE UNITED STATES
AGRICULTURE HANDBOOK NUMBER 335
Revised October 1980
Honey is essentially a highly concentrated
water solution of two sugars, dextrose and levulose, with small
amounts of at least 22 other more complex sugars. Many other
substances also occur in honey, but the sugars are by far the
major components. The principal physical characteristics and
behavior of honey are due to its sugars, but the minor constituents
- such as flavoring materials, pigments, acids, and minerals
- are largely responsible for the differences among individual
honey types.
Honey, as it is found in the hive, is a truly remarkable material,
elaborated by bees with floral nectar, and less often with honeydew.
Nectar is a thin, easily spoiled sweet liquid that is changed
("ripened") by the honey bee to a stable, high-density,
high-energy food. The earlier U.S. Food and Drug Act defined
honey as "the nectar and saccharine exudation of plants,
gathered, modified, and stored in the comb by honey bees (Apis
mellifera and A. dorsata); is levorotatory; contains
not more than 25% water, not more than 0.25% ash, and not more
than 8% sucrose." The limits established in this definition
were largely based on a survey published in 1908. Today, this
definition has an advisory status only, but is not totally correct,
as it allows too high a content of water and sucrose, is too
low in ash, and makes no mention of honeydew.
Colors of honey form a continuous range from very pale yellow
through ambers to a darkish red amber to nearly black. The variations
are almost entirely due to the plant source of the honey, although
climate may modify the color somewhat through the darkening action
of heat.
The flavor and aroma of honey vary even more than the color.
Although there seems to be a characteristic "honey flavor,"
almost an infinite number of aroma and flavor variations can
exist. As
with color, the variations appear to be governed by the floral
source. In general, light-colored honey is mild in flavor and
a darker honey has a more pronounced flavor. Exceptions to the
rule sometimes endow a light honey with very definite specific
flavors. Since flavor and aroma judgments are personal, individual
preference will vary, but with the tremendous variety available,
everyone should be able to find a favorite honey.
(1) Research leader and
research chemist, respectively, Science and Education Administration,
Eastern Regional Research Center, Philadelphia, Pa. 19118.
Composition of Honey
By far, the largest portion of the dry
matter in honey consists of the sugars. This very concentrated
solution of several sugars results in the characteristic physical
properties of honey - high viscosity, "stickiness,"
high density, granulation tendencies, tendency to absorb moisture
from the air, and immunity from some types of spoilage. Because
of its unique character and its considerable difference from
other sweeteners, chemists have long been interested in its composition
and food technologists sometimes have been frustrated in attempts
to include honey in prepared food formulas or products. Limitations
of methods available to earlier researchers made their results
only approximate in regard to the true sugar composition of honey.
Although recent research has greatly improved analytical procedures
for sugars, even now some compromises are required to make possible
accurate analysis of large numbers of honey samples for sugars.
An analytical survey of U.S. honey is reported in Composition
of American Honeys, Technical Bulletin 1261, published by
the U.S. Department of Agriculture in 1962. In this survey, considerable
effort was made to obtain honey samples from all over the United
States and to include enough samples of the commercially significant
floral types that the results, averaged by floral type, would
be useful to the beekeeper and packer and also to the food technologist.
In addition to providing tables of composition of U.S. honeys,
some general conclusions were reached in the bulletin on various
factors affected by honey composition.
Where comparisons were made of the composition of the same types
of honey from 2 crop years, relatively small or no differences
were found. The same was true for the same type of honey from
various locations. As previously known, dark honey is higher
than light honey in ash (mineral) and nitrogen content. Averaging
results by regions showed that eastern and southern honeys were
darker than average, whereas north-central and intermountain
honeys were lighter. The north-central honey was higher than
average in moisture, and the intermountain honey was more heavy
bodied. Honey from the South Atlantic States showed
the least tendency to granulate, whereas the intermountain honey
had the greatest tendency.
The technical bulletin includes complete analyses of 490 samples
of U.S. floral honey and 14 samples of honeydew honey gathered
from 47 of the 50 States and representing 82 "single"
floral types and 93 blends of "known" composition.
For the more common honey types, many samples were available
and averages were calculated by computer for many floral types
and plant families. Also given in this bulletin are the average
honey composition for each State and region and detailed discussions
of the effects of crop year, storage, area of production, granulation,
and color on composition. Some of the tabular data are included
in this handbook.
Table 1 gives
the average value for all of the constituents analyzed in the
survey and also lists the range of values for each constitutent.
The range shows the great variability for all honey constituents.
Most of the constituents listed are familiar. Levulose and dextrose
are the simple sugars making up most of the honey. Fructose and
glucose are other commonly used names for these sugars. Sucrose
(table sugar) also is present in honey, and is one of the main
sugars in nectar, along with levulose and dextrose. "Maltose"
is actually a mixture of several complex sugars, which are analyzed
collectively and reported as maltose. Higher sugars is a more
descriptive term for the material formerly called honey dextrin.
The undetermined value is found by adding all the sugar percentages
to the moisture value and subtracting from 100. The active acidity
of a material is expressed as pH; the larger the number the lower
is the active acidity. The lactone is a newly found component
of honey. Lactones may be considered to be a reserve acidity,
since by chemically adding water to them (hydrolysis) an acid
is formed. The ash is, of course, the material remaining after
the honey is burned and represents mineral matter. The nitrogen
is a measure of the protein material, including the enzymes,
and diastase is a specific starch-digesting enzyme.
Most of these constituents are expressed in percent, that is,
parts per hundred of honey. The acidity is reported differently.
In earlier times, acidity was reported as percent formic acid.
We now know that there are many acids in honey, with formic acid
being one of the least important. Since a sugar acid, gluconic
acid, has been found to be the principal one in honey, these
results could be expressed as "percent gluconic acid"
by multiplying the numbers in the table by 0.0196. Since actually
there are many acids in honey, the term "milliequivalents
per kilogram" is used to avoid implying that only one acid
is found in honey. This figure is such that it properly expresses
the acidity of a honey sample independently of the kind or kinds
of acids present.
In table 1,
the differences between floral honey and honeydew honey(2) can
be seen. Floral honey is higher in simple sugars (levulose and
dextrose), lower in disaccharides and higher sugars (dextrins),
and contains much less acid. The higher amount of mineral salts
(ash) in honeydew gives it a less active acidity (higher PH).
The nitrogen content reflecting the amino acids and protein content
is also higher in honeydew.
The main sugars in the common types of honey are shown in table 2. Levulose
is the major sugar in all the samples, but there are a few types,
not on the list, that contain more dextrose than levulose (dandelion
and the blue curls). This excess of levulose over dextrose is
one way that honey differs from commercial invert sugar. Even
though honey has less dextrose than levulose, it is dextrose
that crystallizes when honey granulates, because it is less soluble
in water than is levulose. Even though honey contains an active
sucrose-splitting enzyme, the sucrose level in honey never reaches
zero.
Honey varies tremendously in color and flavor, depending largely
on its floral source. Its composition also varies widely, depending
on its floral sources (table
2). Although hundreds of kinds of honey are produced in this
country, only about 25 or 30 are commercially important and available
in large quantities. Until the comprehensive survey of honey
composition was published in 1962, the degree of compositional
variation was not known. This lack of information hindered the
widespread use of honey by the food industry.
Water Content
The natural moisture of honey
in the comb is that remaining from the nectar after ripening.
The amount of moisture is a function of the factors involved
in ripening, including weather conditions and original moisture
of the nectar. After extraction of the honey, its moisture content
may change, depending on conditions of storage. It is one of
the most important characteristics of honey influencing keeping
quality, granulation, and body.
Beekeepers as well as honey buyers know that the water content
of honey varies greatly. It may range between 13 and 25 percent.
According to the United States Standards for Grades of Extracted
Honey, honey may not contain more than 18.6 percent moisture
to qualify for U.S. grade A (U.S. Fancy) and U.S. grade B (U.S.
Choice). Grade C (U.S. Standard) honey may contain up to 20 percent
water; any higher amount places a honey in U.S. grade D (Substandard).
These values represent limits and do not indicate the preferred
or proper moisture content for honey. If honey has more than
17 percent moisture and contains a sufficient number of yeast
spores, it will ferment. Such honey should be pasteurized, that
is, heated sufficiently to kill such organisms. This is particularly
important if the honey is to be "creamed" or granulated,
since this process results in a slightly higher moisture level
in the liquid part. On the other hand, it is possible for honey
to be too low in moisture from some points of view. In the West,
honey may have a moisture content as low as 13 to 14 percent.
Such honey is somewhat difficult to handle, though it is most
useful in blending to reduce moisture content. It contains over 6 percent more honey solids than
a product of 18.6 percent moisture.
In the 490 samples of honey analyzed in the Department's Technical
Bulletin 1261, the average moisture content was 17.2 percent.
Samples ranged between 13.4 and 22.9 percent, and the standard
deviation was 1.46. This means that 68 percent of the samples
(or of all U.S. honey) will fall within the limits of 17.2 ±
1.46 percent moisture (15.7 - 18.7); 95.5 percent of all U.S.
honey will fall within the limits of 17.2 ± 2.92 percent
moisture (14.3 - 20.1).
In the same bulletin, a breakdown of average moisture contents
by geographic regions is shown. These values (percent) are North
Atlantic, 17.3; East North Central, 18.0; West North Central,
18.2; South Atlantic, 17.7; South Central, 17.5;
Intermountain West, 16.0; and West, 16.1.
Sugars
Honey is above all a carbohydrate
material, with 95 to 99.9 percent of the solids being sugars,
and the identity of these sugars has been studied for many years.
Sugars are classified according to their size or the complexity
of the molecules of which they are made. Dextrose (glucose) and
levulose (fructose), the main sugars in honey, are simple sugars,
or monosaccharides, and are the building blocks for the more
complex honey sugars. Dextrose and levulose account for about
85 percent of the solids in honey.
Until the middle of this century, the sugars of honey were thought
to be a simple mixture of dextrose, levulose, sucrose (table
sugar), and an ill-defined carbohydrate material called "honey
dextrin." With the advent of new methods for separating
and analyzing sugars, workers in Europe, the United States, and
Japan have identified many sugars in honey after separating them
from the complex honey mixture. This task has been accomplished
using a variety of physical and chemical methods.
Dextrose and levulose are still by far the major sugars in honey,
but 22 others have been found. All of these sugars are more complex
than the monosaccharides, dextrose and levulose. Ten disaccharides
have been identified: sucrose, maltose, isomaltose, maltulose,
nigerose, turanose, kojibiose, laminaribiose, a, B-trehalose,
and gentiobiose. Ten trisaccharides are present: melezitose,
3-a-isomaltosylglucose, maltotriose, l-kestose, panose,
isomaltotriose, erlose, theanderose, centose, and isopanose.
Two more complex sugars, isomaltotetraose and isomaltopentaose,
have been identified. Most of these sugars are present in quite
small quantities.
Most of these sugars do not occur in nectar, but are formed either
as a result of enzymes added by the honeybee during the ripening
of honey or by chemical action in the concentrated, somewhat
acid sugar mixture we know as honey.
Acids
The flavor of honey results from
the blending of many "notes," not the least being a
slight tartness or acidity. The acids of honey account for less
than 0.5 percent of the solids, but this level contributes not
only to the flavor, but is in part responsible for the excellent
stability of honey against microorganisms. Several acids have
been found in honey, gluconic acid being the major one. It arises
from dextrose through the action of an enzyme called glucose
oxidase. Other acids in honey are formic, acetic, butyric, lactic,
oxalic, succinic, tartaric, maleic, pyruvic, pyroglutamic, a-ketoglutaric,
glycollic, citric, malic, 2- or 3-phosphoglyceric acid, a-
or B-glycerophosphate, and glucose 6-phosphate.
Proteins and Amino Acids
It will be noted in table
1 that the amount of nitrogen in honey is low, 0.04 percent
on the average, though it may range to 0.1 percent. Recent work
has shown that only 40 to 65 percent of the total nitrogen in
honey is in protein, and some nitrogen resides in substances
other than proteins, namely the amino acids. Of the 8 to 11 proteins
found in various honeys, 4 are common to all, and appear to originate
in the bee, rather than the nectar. Little is known of many proteins
in honey, except that the enzymes fall into this class.
The presence of proteins causes honey to have a lower surface
tension than it would have otherwise, which produces a marked
tendency to foam and form scum and encourages formation of fine
air bubbles. Beekeepers familiar with buckwheat honey know how
readily it tends to foam and produce surface scum, which is largely
due to its relatively high protein content.
The amino acids are simple compounds obtained when proteins are
broken down by chemical or digestive processes. They are the
"building blocks" of the proteins. Several of them
are essential to life and must be obtained in the diet. The quantity
of free amino acids in honey is small and of no nutritional significance.
Breakthroughs in the separation and analysis of minute quantities
of material (chromatography) have revealed that various honeys
contain 11 to 21 free amino acids. Proline, glutamic acid, alanine,
phenylalanine, tyrosine, leucine, and isoleucine are the most
common, with proline predominating.
Amino acids are known to react slowly, or more rapidly by heating,
with sugars to produce yellow or brown materials. Part of the
darkening of honey with age or heating may be due to this.
Minerals
When honey is dried and burned,
a small residue of ash invariably remains, which is the mineral
content. As shown in table
1, it varies from 0.02 to slightly over 1 percent for a floral
honey, averaging about 0.17 percent for the 490 samples analyzed.
Honeydew honey is richer in minerals, so much so that its mineral
content is said to be a prime cause of its unsuitability for
winter stores. Schuette and his colleagues at the University
of Wisconsin have examined the mineral content of light and dark
honey. They reported the following average values:
| Mineral |
Light honey
(p.p.m.) |
Dark honey
(p.p.m.) |
|
| Potassium |
205 |
1,676 |
| Chlorine |
52 |
113 |
| Sulfur |
58 |
100 |
| Calcium |
49 |
51 |
| Sodium |
15 |
76 |
| Phosphorus |
35 |
47 |
| Magnesium |
19 |
35 |
| Silica |
22 |
36 |
| Iron |
2.4 |
9.4 |
| Manganese |
.30 |
4.09 |
| Copper |
.29 |
.56 |
Enzymes
One of the characteristics that sets honey apart from all other
sweetening agents is the presence of enzymes. These conceivably
arise from the bee, pollen, nectar, or even yeasts or micro-organisms
in the honey. Those most prominent are added by the bee during
the conversion of nectar to honey. Enzymes are complex protein
materials that under mild conditions bring about chemical changes,
which may be very difficult to accomplish in a chemical laboratory
without their aid. The changes that enzymes bring about throughout
nature are essential to life.
Some of the most important honey enzymes are invertase, diastase,
and glucose oxidase.
Invertase, also known as sucrase or saccharase splits sucrose
into its constitutent simple sugars, dextrose, and levulose.
Other more complex sugars have been found recently to form in
small amounts during this action and in part explain the complexity
of the minor sugars of honey. Although the work of invertase
is completed when honey is ripened, the enzyme remains in the
honey and retains its activity for some time. Even so, the sucrose
content of honey never reaches zero. Since the enzyme also synthesizes
sucrose, perhaps the final low value for the sucrose content
of honey represents an equilibrium between splitting and forming
sucrose.
Diastase (amylase) digests starch to simpler compounds but no
starch is found in nectar. What its function is in honey is not
clear. Diastase appears to be present in varying amounts in nearly
all honey and it can be measured. It has probably had the greatest
attention in the past, because it has been used as a measure
of honey quality in several European countries.
Glucose oxidase converts dextrose to a related material, a gulconolactone,
which in turn forms gluconic acid, the principal acid in honey.
Since this enzyme previously was shown to be in the pharyngeal
gland of the honey bee, this is probably the source. Here, as
with other enzymes, the amount varies in different honeys. In
addition to gluconolactone, glucose oxidase forms hydrogen peroxide
during its action on dextrose, which has been shown to be the
basis of the heat-sensitive antibacterial activity of honey.
Other enzymes are reported to be present in honey, including
catalase and an acid phosphatase. All the honey enzymes can be
destroyed or weakened by heat.
Properties of Honey
Because of honey's complex and unusual
composition, it has several interesting attributes. In addition,
honey has some properties, because of its composition, that make
it difficult to handle and use. With modern technology, however,
methods have been established to cope with many of these problems.
Antibacterial Activity
An ancient use for honey was
in medicine as a dressing for wounds and inflammations. Today,
medicinal uses of honey are largely confined to folk medicine.
On the other hand, since milk can be a carrier of some diseases,
it was once thought that honey might likewise be such a carrier.
Some years ago this idea was examined by adding nine common pathogenic
bacteria to honey. All the bacteria died within a few hours or
days. Honey is not a suitable medium for bacteria for two reasons
- it is fairly acid and it is too high in sugar content for growth
to occur. This killing of bacteria by high sugar content is called
osmotic effect. It seems to function by literally drying out
the bacteria. Some bacteria, however, can survive in the resting
spore form, though not grown in honey.
Another type of antibacterial property of honey is that due to
inhibine. The presence of an antibacterial activity in honey
was first reported about 1940 and confirmed in several laboratories.
Since then, several papers were published on this subject. Generally,
most investigators agree that inhibine (name used by Dold, its
discoverer, for antibacterial activity) is sensitive to heat
and light. The effect of heat on the inhibine content, of honey
was studied by several investigators. Apparently, heating honey
sufficiently to reduce markedly or to destroy its inhibine activity
would deny it a market as first-quality honey in several European
countries. The use of sucrase and inhibine assays together was
proposed to determine the heating history of commercial honey.
Until 1963, when White showed that the inhibine effect was due
to hydrogen peroxide produced and accumulated in diluted honey,
its identity remained unknown. This material, well known for
its antiseptic properties, is a byproduct of the formation of
gluconic acid by an enzyme that occurs in honey, glucose oxidase.
The peroxide can inhibit the growth of certain bacteria in the
diluted honey. Since it is destroyed by other honey constituents,
an equilibrium level of peroxides will occur in a diluted honey,
its magnitude depending on many factors such as enzyme activity,
oxygen availability, and amounts of peroxide-destroying materials
in the honey. The amount of inhibine (peroxide accumulation)
in honey depends on floral type, age, and heating.
A chemical assay method has been developed that rapidly measures
peroxide accumulation in diluted honey. By this procedure, different
honeys have been found to vary widely in the sensitivity of their
inhibine to heat. In general, the sensitivity is about the same
as or greater than that of invertase and diastase in honey.
Food Value
Honey is primarily a high-energy
carbohydrate food. Because its distinct flavors cannot be found
elsewhere, it is an enjoyable treat. The honey sugars are largely
the easily digestible "simple sugars," similar to those
in many fruits. Honey can be regarded as a good food for both
infants and adults.
The protein and enzymes of honey, though used as indicators of
heating history and hence table quality in some countries, are
not present in sufficient quantities to be considered nutritionally
significant. Several of the essential vitamins are present in
honey, but in insignificant levels. The mineral content of honey
is variable, but darker honeys have significant quantities of
minerals.
Granulation
Dextrose, a major sugar in honey,
can spontaneously crystallize from any honeys in the form of
its monohydrate. This sometimes occurs when the moisture level
in honey is allowed to drop below a certain level.
A large part of the honey sold to consumers in the United States
is in the liquid form, much less in a finely granulated form
known as "honey spread" or finely granulated honey,
and even less as comb honey. The consumer appears to be conditioned
to buying liquid honey. At least sales of the more convenient
spread form have never approached those of liquid honey.
Since the granulated state is natural for most of the honey produced
in this country, processing is required to keep it liquid. Careful
application of heat to dissolve "seed" crystals and
avoidance of subsequent "seeding" will usually suffice
to keep a honey liquid for 6 months. Damage to color and flavor
can result from excessive or improperly applied heat. Honey that
has granulated can be returned to liquid by careful heating.
Heat should be applied indirectly by hot water or air, not by
direct flame or high-temperature electrical heat. Stirring accelerates
the dissolution of crystals. For small containers, temperatures
of 140ºF for 30 minutes usually will suffice.
If unheated honey is allowed to granulate naturally, several
difficulties may arise. The texture may be fine and smooth or
granular and objectionable to the consumer. Furthermore, a granulated
honey becomes more susceptible to spoilage by fermentation, caused
by natural yeast found in all honeys and apiaries. Quality damage
from poor texture and fermented flavors usually is far greater
than any caused by the heat needed to eliminate these problems.
Finely granulated honey may be prepared from a honey of proper
moisture content (17.5 percent in summer, 15 percent in winter)
by several processes. All involve pasteurization to eliminate
fermentation, followed by addition at room temperature of 5 to
10 percent of a finely granulated "starter" of acceptable
texture, thorough mixing, and storage at 55º to 60ºF
in the retail containers for about a week. The texture remains
acceptable if storage is below about 80º to 85º.
Deterioration of Quality
Fermentation. - Fermentation of honey is caused by the action
of sugar-tolerant yeasts upon the sugars dextrose and levulose,
resulting in the formation of ethyl alcohol and carbon dioxide.
The alcohol in the presence of oxygen then may be broken down
into acetic acid and water. As a result, honey that has fermented
may taste sour.
The yeasts responsible for fermentation occur naturally in honey,
in that they can germinate and grow at much higher sugar concentrations
than other yeasts, and, therefore, are called "osmophilic."
Even so there are upper limits of sugar concentration beyond
which these yeasts will not grow. Thus, the water content of
a honey is one of the factors concerned in spoilage by fermentation.
The others are extent of contamination by yeast spores (yeast
count) and temperature of storage.
Honey with less than 17.1 percent water will not ferment in a
year, irrespective of the yeast count. Between 17.1 and 18 percent
moisture, honey with 1,000 yeast spores or less per gram will
be safe for a year. When moisture is between 18.1 and 19 percent,
not more than 10 yeast spores per gram can be present for safe
storage. Above 19 percent water, honey can be expected to ferment
even with only one spore per gram of honey, a level so low as
to be very rare.
When honey granulates, the resulting increased moisture content
of the liquid part is favorable for fermentation. Honey with
a high moisture content will not ferment below 50ºF or above
about 80º. Honey even of relatively low water content will
ferment at 60º. Storing at temperatures over 80º to
avoid fermentation is not practical as it will damage honey.
E. C. Martin has studied the mechanism and course of yeast fermentation
in honey in conjunction with his work on the hygroscopicity of
honey. He confirmed that when honey absorbs moisture, which occurs
when it is stored above 60-percent relative humidity, the moisture
content at first increases mostly at the surface before the water
diffuses into the bulk of the honey. When honey absorbs moisture,
yeasts grow aerobically (using oxygen) at the surface and multiply
rapidly, whereas below the surface the growth is slower.
Fermenting honey is usually at least partly granulated and is
characterized by a foam or froth on the surface. lt will foam
considerably when heated. An odor as of sweet wine or fermenting
fruit may be detected. Gas production may be so vigorous as to
cause honey to overflow or burst a container. The off-flavors
and odors associated with fermentation probably arise from the
acids produced by the yeasts.
Honey that has been fermented can sometimes be reclaimed by heating
it to 150ºF for a short time. This stops the fermentation
and expels some of the off-flavor. Fermentation in honey may
be avoided by heating to kill yeasts. Minimal treatments to pasteurize
honey are as follows:
Temperature
(ºF):
|
Heating time (minutes)
|
|
128 |
470 |
|
130 |
170 |
|
135 |
60 |
|
140 |
42 |
|
145 |
7.5 |
|
150 |
2.8 |
|
155 |
1.0 |
|
160 |
.4 |
The following summarize the important aspects of fermentation:
1. All honey should be considered to contain yeasts.
2. Honey is more liable to fermentation after granulation.
3. Honey of over 17 percent water may ferment and over 19 percent
water will ferment.
4. Storage below 50ºF will prevent fermentation during such
storage, but not later.
5. Heating honey to 150ºF for 30 minutes will destroy honey
yeasts and thus prevent fermentation.
Quality loss by heating and storing - The other principal
types of honey spoilage, damage by over-heating and by improper
storing, are related to each other. In general, changes that
take place quickly during heating also occur over a longer period
during storage with the rate depending on the temperature. These
include darkening, loss of fresh flavor, and formation of off-flavor
(caramelization).
To keep honey in its original condition of high quality and delectable
flavor and fragrance is possibly the greatest responsibility
of the beekeeper and honey packer. At the same time it is an
operation receiving perhaps less attention from the producer
than any other and one requiring careful consideration by packers
and wholesalers. To do an effective job, one must know the factors
that govern honey quality, as well as the effects of various
beekeeping and storage practices on honey quality. The factors
are easily determined, but only recently are the facts becoming
known regarding the effects of processing temperatures and storage
on honey quality.
To be of highest quality, a honey - whether liquid, crystallized,
or comb - must be well ripened with proper moisture content;
it must be free of extraneous materials, such as excessive pollen,
dust, insect parts, wax, and crystals if liquid; it must not
ferment; and above all it must be of excellent flavor and aroma,
characteristic of the particular honey type. It must, of course,
be free of off-flavors or odors of any origin. In fact, the more
closely it resembles the well-ripened honey as it exists in the
cells of the comb, the better it is.
Several beekeeping practices can reduce the quality of the extracted
product. These include combining inferior floral types, either
by mixing at extracting time or removing the crop at incorrect
times, extraction of unripe honey, extraction of brood combs,
and delay in settling and straining. However, we are concerned
here with the handling of honey from its extraction to its sale.
During this time improper settling, straining, heating, and storage
conditions can make a superb honey into just another commercial
product.
The primary objective of all processing of honey is simple -
to stabilize it. This means to keep it free of fermentation and
to keep the desired physical state, be it liquid or finely granulated.
Methods for accomplishing these objectives have been fairly well
worked out and have been used for many years. Probably improvements
can be made. The requirements for stability of honey are more
stringent now than in the past, with honey a world commodity
and available in supermarkets the year around. Government price
support and loan operations require storage of honey, and market
conditions also may require storage at any point in the handling
chain, including the producer, packer, wholesaler, and exporter.
The primary operation in the processing of honey is the application
and control of heat. If we consider storage to be the application
of or exposure to low amounts of heat over long periods, it can
be seen that a study of the effects of heat on honey quality
can have a wide application.
Any assessment of honey quality must include flavor considerations.
The objective measurement of changes in flavor, particularly
where they are gradual, is most difficult. We have measured the
accumulation of a decomposition product of the sugars (hydroxymethylfurfural
or HMF) as an index of heat-induced chemical change in the honey.
Changes in flavor, other than simple loss by evaporation, also
may be considered heat-induced chemical changes.
To study the effects of treatment on honey, we must use some
properties of honey as indices of change. Such properties should
relate to the quality or commercial value of honey. The occurrence
of granulation of liquid honey, liquefaction or softening of
granulated honey, and fermentation as functions of storage conditions
has been reported; also, color is easily measured.
As indicators of the acceptability of honey for table use, Europeans
have for many years used the amount of certain enzymes and HMF
in honey. They considered that heating honey sufficiently to
destroy or greatly lower its enzyme content or produce HMF reduced
its desirability for most uses. A considerable difference has
been noted in the reports by various workers on the sensitivity
to heat of enzymes, largely diastase and invertase, in honey.
Only recently has it been noted that storage alone is sufficient
to reduce enzyme content and produce HMF in honey. Since some
honey types frequently exported to Europe are naturally low in
diastase, the response of diastase and invertase to storage and
processing is of great importance for exporters.
A study was made of the effects of heating and storage on honey
quality and was based on the results with three types of honey
stored at six temperatures for 2 years. The results were used
to obtain predictions of the quality life of honey under any
storage conditions. The following information is typical of the
calculations based on this work.
At 68ºF, diastase in honey has a half-life of 1,500 days,
nearly 4 years. Invertase is more heat sensitive, with a half-life
at 68º of 800 days, or about 2-1/4 years. Thus there are
no problems here. By increasing the storage temperature to 77º,
half the diastase is gone in 540 days, or 1-1/3 years, and half
the invertase disappears in 250 days, or about 8 months. These
periods are still rather long and there would seem to be nothing
to be concerned about. However, temperatures in the 90's for
extended periods are not at all uncommon: 126 days (4 months)
will destroy half the diastase and about 50 days (2 months) will
eliminate half the invertase. As the temperature increases, the
periods involved become shorter and shorter until the processing
temperatures are reached. At 130º, 2-1/2 days would account
for half the diastase and in 13 hours half the invertase is gone.
A recommended temperature for pasteurization of honey is 145ºF
for 30 minutes. At this temperature diastase has a half-life
of 16 hours and invertase only 3 hours. At first glance this
might seem to present no problems, but it must be remembered
that unless flash heating and immediate cooling are used, many
hours will be required for a batch
of honey to cool from 145º to a safe temperature.
If we proceed further to a temperature often recommended for
preventing granulation, 160ºF for 30 minutes, the necessity
of prompt cooling becomes highly important. At 160º, 2-1/2
hours will destroy half of the diastase, but half of the more
sensitive invertase will be lost in 40 minutes. This treatment
then cannot be recommended for any honey in which a good enzyme
level is needed, as for export.
The damage done to honey by heating and by storage is the same.
For the lower storage temperatures, simply a much longer time
is required to obtain the same result. It must be remembered
that the effects of processing and storage are additive. It is
for this reason that proper storage is so important. A few periods
of hot weather can offset the benefits of months of cool storage
- 10 days at 90ºF are equivalent to 100 to 120 days at 70º.
An hour at 145º in processing will cause changes equivalent
to 40 days' storage at 77º.
An easy way for beekeepers to decide whether they have storage
or processing deterioration is to take samples of the fresh honey,
being careful that the samples are fairly representative of the
batch, and place them in a freezer for the entire period. At
the end of this time, they should warm the samples to room temperature
and compare them by color, flavor, and aroma with the honey in
common storage. In some parts of the United States, the value
of the difference can reach 1-1/2 cents per pound in a few months.
Such figures certainly would justify expenditures for temperature
control.
People who store honey are in a dilemma. They must select conditions
that will minimize fermentation, undesirable granulation, and
heat damage. Fermentation is strongly retarded below 50ºF
and above 100º. Granulation is accelerated between 55º
and 60º and initiated by fluctuation at 50º to 55º.
The best condition for storing unpasteurized honey seems to be
below 50º, or winter temperatures over much of the United
States. Warming above this range in the spring can initiate active
fermentation in such honey, which is usually granulated and thus
even more susceptible.
References
DONER, L. W.
1977. THE SUGARS OF
HONEY-A REVIEW. Journal of Science and Agriculture.
TOWNSEND, G. F
1961. PREPARATION OF HONEY FOR MARKET. 24 p. Ontario Department
of Agriculture Publication 544.
WHITE, J. W. JR.
1975. HONEY. In Grout, R. A., ed., The hive and the honey bee,
p. 491-530. Dadant & Sons, Inc., Hamilton, Ill.
_________
1975. COMPOSITION AND PHYSICAL PROPERTIES OF HONEY.
In E. Crane, ed., Honey Review, p. 157-239. Heinemann,
London.
______ M. L. RIETHOP, M. H. SUBERS, and I. KUSHNIR.
1962. COMPOSITION OF AMERICAN HONEYS. 124 p. U.S. Department
of Agriculture Technical Bulletin 1261.
|
