1
Hemp seed oil:
A source of valuable
essential fatty acids
Jean-Luc Deferne1 and David W. Pate2
1 International College of
Hospitality Administration,
Englisch-Gruss-Strasse 43, CH-3900 Brig, Switzerland .
2 HortaPharm B.V.,
Schinkelhavenkade 6, 1075VS
Amsterdam, The Netherlands.
Deferne, J.L. and D. W. Pate, 1996. Hemp
seed oil: A source of valuable essential fatty acids. Journal of the
International Hemp Association 3(1): 1, 4-7.
Interest in Cannabis has largely focused on its content of
psychoactive substances (cannabinoids) or its potential industrial use as a source of
cellulose fibre. While the whole seed has long been used as a source of food, its
potential health contribution has never gained much attention. Hemp seed shares with
no other plant resource, both a high content of easily digestible complete protein and a
rich endowment of oil providing a favorable ratio of the linoleic (C18:2w6) and linolenic
(C18:3w3) essential fatty acids required for proper human nutrition, in addition to a
significant contribution of gamma-linolenic (C18:3w6) acid of potential therapeutic
efficacy. With a recently acquired knowledge concerning the importance of these
fatty acids in the human diet, it is time to both intensify research on their variable
occurence among varieties of hemp seed, and investigate methods of oil extraction and
storage suitable for their preservation.
Figure 1. Cannabis seed, magnified (Courtesy of VIR.)
Introduction
Cannabis is probably one of the first
plants to have been used (and later cultivated) by people (Schultes 1973).
Throughout history and in separate parts of the world, hemp has often been an important
plant revered for its psychoactivity and useful for medicine, as a source of fibre, and
for the food provided by its seed. The seed oil is particularly nutritious and its
properties and potentials are herein explored.
The fruit of hemp is not a true seed, but an "achene", a tiny
nut covered by a hard shell (Small 1979, Paris and Nahas 1984). These are consumed
whole, used in food and folk medicinal preparations (Jones 1995) or employed as a feed for
birds and fishes. Whole hemp seed contains approximately 20-25% protein, 20-30%
carbohydrates and 10-15% insoluble fiber (Theimer and Mölleken 1995, Theimer 1996), as
well as a rich array of minerals, particularly phosphorous, potassium, magnesium, sulfur
and calcium, along with modest amounts of iron and zinc (Jones 1995, Wirtschafter 1995),
the latter of which is an important enzyme co-factor for human fatty acid metabolism
(Erasmus 1993). It is also a fair source of carotene, a "Vitamin A"
precursor, and is a potentially important contributor of dietary fiber. Most hemp
seed also contains approximately 25-35% oil, although one variety grown in Russia called
"olifera" reportedly contains 40% (Small 1979, Mathieu 1980) and a Chinese
variety was claimed to slightly exceed this figure (Jones 1995).
This highly polyunsaturated oil has uses similar to that of linseed oil
(e.g., fuel for lighting, printers ink, wood preservative), but also has been
employed as a raw material for soaps and detergents (Olschewski 1995) and as an emollient
in body-care products (Rausch 1995). However, it is the nutritional qualities of the
oil that are particularly important. The crushed seed by-product is suitable for
animal feed as well as a human staple (Grinspoon and Bakalar 1993, Small 1979, Paris and
Nahas 1984), due to its spectrum of amino acids, including all 8 of those essential to the
human diet (Jones 1995, Wirtshafter 1995), as well as carbohydrates and a small amount of
residual oil. Its protein is primarily edestin (St. Angelo et al. 1968), a
highly assimilable globular protein of a type similar to the albumin found in egg whites
and blood. However, heat-treating whole hemp seed denatures this protein (Stockwell et
al. 1964) and renders it insoluble, possibly affecting digestibility.
An ideal seed hemp variety would produce a high yield of seed (normally
0.5-1.0 t/ha) containing a high percentage of good quality oil. Highly branched
varieties are usually preferred. For seed production, male plants are sometimes
removed after pollination has occurred, in order to leave more space for female
plants. Mathieu et al. (1980) have noted that seed yield can be doubled using
monoecious varieties, although this sexual type suffers some inbreeding depression.
Cultivation of a monoecious strain in Switzerland yielded up to approximately 1.5 metric
tons of seed per hectare in 1995 (unpublished data), but lower yields are generally
reported (Mathieu 1980, Höppner and Menge-Hartmann 1994). Highest seed yields are
obtainable with unisex female varieties, such as Uniko-B (Bócsa 1995). The number
of flowers per plant and, therefore, the quantity of seed produced, can be increased by
"topping" the plants when they are 30-50 cm high. Maximum seed yield
requires that hemp be sown at a much lower density than for fibre (Reichert 1994).
However, weeds can prosper if planting density is too sparse (e.g., 25/m2 ).
Extraction methods
Extraction of oil from hemp seed is not being
carried out on a large scale at the present time. That being processed, is sometimes
relatively unhomogenous, mature seeds mixed with green ones. This is due to the
difficulty of finding the optimal time for harvesting, since not all seeds reach maturity
simultaneously, especially in hemp undeveloped for seed production. The presence of
unripe seeds not only increases seed crop moisture content, it also lowers oil yield and
modifies its taste.
After harvest, hemp seed undergoes a drying process that reduces its
moisture content to 10% or less, so as to prevent sprouting during storage. Batches
of this material are then fed into a hydraulic screw press and a pressure of 500 bars is
progressively applied, resulting in only a minor elevation in temperature. Best
quality oil is obtained from the first fractions recovered. Approximately 35% of the
available oil remains in the seed cake (Jones 1995). The pressing process is
sometimes repeated with this crushed residue to obtain a small additional amount of oil,
although quality is decreased.
This "cold pressing" does not allow an extraction yield equal
to that of techniques employing solvents or high temperatures, but it has the advantage of
minimizing degradative changes in the oil. A small amount of oil is also unrecovered
during the subsequent filtration process. Further refining procedures should be
avoided in order to preserve the native qualities of this product. Bottling must
occur quickly and filling under nitrogen into opaque bottles, then refrigerating, offers
significant protection against oil degradation due to oxidation and the action of light,
although freezing is necessary for long-term storage. Addition of anti-oxidants
extends shelf life of the product at room temperature (McEvoy et al. 1996).
Oil composition and properties
Non-refined hemp seed oil extracted by
cold-pressing methods varies from off-yellow to dark green and has a pleasant nutty taste,
sometimes accompanied by a touch of bitterness. The seed (and therefore the
extracted oil) normally does not contain significant amounts of psychoactive substances
(Paris and Nahas 1984, Vieira et al. 1967). Trace amounts of THC, sometimes
found upon analysis, are probably due to contamination of the seed by adherent resin or
other plant residues (Matsunaga et al. 1990, Mathé and Bócsa 1995), although
reports to the contrary exist (e.g., Patwardhan et al. 1978).
Analytical data reported for the fatty acid composition of hemp seed
oil (Weil 1993, Kralovansky and Marthé-Schill 1994, Höppner and Menge-Hartmann 1994,
Theimer and Mölleken 1995, Wirtshafter 1995), together with an analysis performed on an
oil produced in Switzerland from a monoecious variety (unpublished data), reveals that it
is unusually high in polyunsaturated fatty acids (70-80%), while its content in saturated
fatty acids (below 10%) compares favorably with the least saturated commonly consumed
vegetable oils (Table 1). This high degree of unsaturation explains its extreme
sensitivity to oxidative rancidity, as the chemical "double-bonds" that provide
such unsaturation are vulnerable to attack by atmospheric oxygen. This degradation
is accelerated by heat or light. For this reason, the oil is unsatisfactory for
frying or baking, although moderate heat for short periods is probably tolerable. It
is best consumed as a table oil, on salads or as a butter/margarine substitute for dipping
bread, similar in use to olive oil. Proper steam sterilization of the seed probably
does not cause significant damage to the oil, but does destroy the integrity of the seed,
allowing penetration by air and molds. If this procedure is required, it should be
done at a legally bonded facility immediately before release of the seed for further
processing. By the same reasoning, one should avoid eating whole hemp seed that has
been subjected to any cooking process, unless reasonably fresh.
The two polyunsaturated essential fatty acids, linoleic acid (C18:2w6)
or "LA" and linolenic acid (C18:3w3) or "LNA", usually account for
approximately 50-70% and 15-25% respectively, of the total seed fatty acid content
(Theimer and Mölleken 1995, Rumyantseva and Lemeshev 1994). Such a 3:1 balance has
been claimed optimal for human nutrition (Erasmus 1993) and is apparently unique among the
common plant oils (Table 1), although black currant seed oil approaches this figure (Table
2). Cannabis seed from tropical environments seems to lack significant
quantities of LNA (ElSohly 1996, Theimer and Mölleken 1995). Temperate variety oils are
less saturated, perhaps due to a natural selection in northern latitudes for oils with a
higher energy storage capacity or which remain liquid at a lower temperature. It
will be interesting to see if this trend continues for Nordic hemp varieties. The
range of results found in some analyses may be attributable to differences in crop
ripeness, since formation of polyunsaturated fatty acids is incomplete in immature Cannabis
seed (ElSohly 1996). This suggests that a maximum ripening of the seed and the
culling of immature seed are important considerations for the production of a quality
oil. Likewise, proper seed sampling criteria are also crucial for representative
analyses.
Table 1. Profile of hemp seed compared to common edible oils (% total fatty acids). Adapted from Erasmus 1993. |
||||||||||||
Less healthy/Chemically stable <----> More nutritious/Chemically unstable |
||||||||||||
"Saturated" | "Monounsaturated" | "Polyunsaturated" | ||||||||||
Palmitic (C16:0) |
Stearic (C18:0) |
Oleic (C18:1w9) |
Linoleic (C18:2w6) |
Linolenic (C18:3w3) |
||||||||
Hemp Soy Canola Wheatgerm Safflower Sunflower Corn Cottonseed Sesame Peanut Avocado Olive Palm Coconut |
6-9 |
2-3 6 7 18 12 12 17 25 13 18 20 16 0 0 |
10-16 26 54 25 13 23 24 21 42 47 70 76 13 6 |
50-70 50 30 50 75 65 59 50 45 29 10 8 2 3 |
15-25 7 7 5 0 0 0 0 0 0 0 0 0 0 |
GLA sources and importance
Gamma-linolenic acid (C18:3w6) or
"GLA" is found in minute quantities in most fats of animal origin (Horrobin
1990a, 1990b). Oats and barley also contain small amounts. Human milk contains some
GLA (Carter 1988), but any significance is probably overshadowed (Erasmus 1993) by the
greater presence of its metabolic derivative dihomo-gamma-linolenic acid or
"DGLA" (C20:3w6).
GLA is available exclusively in health food shops or pharmacies, mostly
as soft gelatine capsules, and is not found in oils usually consumed by most people.
Good sources of GLA include the blue-green alga Spirulina (~1% of dry weight) and
(Table 2) evening primrose oil, black currant seed oil, borage oil and some fungal
oils. Black currant seed oil also reportedly contains up to 9% stearidonic acid
(Erasmus 1993) or "SDA" (C18:4w3), although 2-4% is more usual (Clough
1996). Hemp seed oil from sterilised seed analyzed in the US contained 1.7% GLA
(Weil 1993, Wirtshafter 1995), but higher levels (3-6%) have been measured by German
investigators (Theimer and Mölleken 1995, Theimer 1996), although it is apparently rare
in most tropical varieties of Cannabis (ElSohly 1996). However, absolute amounts of
GLA are not the only criteria for ranking the desirability of an oil. The particular
arrangement of these fatty acids on glycerol (as the natural triglyceride), as well as
differences in possible toxicity among the various oils, may be important (Horrobin 1994).
The potential physiological effects of GLA have been extensively
investigated only recently. In the body, GLA is normally derived from LA and serves
as an intermediary for the formation of longer-chain fatty acids and eicosanoids.
Eicosanoids are short-lived hormone-like substances which fulfill numerous vital roles,
ranging from control of inflammation processes and vascular tone to initiation of
contractions during delivery. The metabolic conversion of LA to GLA is slow in
mammals. Further, it has been suggested that due to stress, ageing or pathology (e.g.,
hypertension, diabetes, etc.), formation of a sufficient amount or balance of
eicosanoids may be impaired. This problem may be relieved by direct GLA
supplementation (Horrobin 1990a, 1990b), although caution is warranted since
overconsumption could be harmful (Phinney 1994). Its alleviating action on
psoriasis, atopic eczema, and mastalgia are already well documented and GLA preparations
are now frequently prescribed for the treatment of the latter two disorders. GLA has
also been under investigation for its beneficial effects in cardiovascular, psychiatric
and immunological disorders (Horrobin 1990a, 1990b, 1992).
If a favorable response to GLA supplementation does not occur,
additional application of stearidonic acid (SDA) or use of black currant seed oil may be
indicated, since the same enzyme (delta-6-desaturase) that converts LA to GLA is
also responsible for converting LNA to SDA (Erasmus 1993). However, relatively few
people suffer from a defect in this enzyme compared to the nearly universal lack of
adequate LNA levels in the diet. A chronic LNA deficit is best acutely treated with
flax seed (fresh linseed) oil, although it is unsuitable for prolonged consumption due to
an imbalance in its LA (14%) to LNA (58%) content, a ratio approximately equal, but
inverse, to that of hemp (Erasmus 1993).
Table 2. Oil profiles of major GLA sources (% total fatty acids). Adapted from various sources. | |||||||
Palmitic (C16:0) |
Stearic (C18:0) |
Oleic (C18:1w9) |
Linoleic (C18:2w6) |
Linolenic (C18:3w3) |
gamma-Linolenic (C18:3w6) |
||
Hemp Evening Primrose Black Currant Borage Fungus (Mucor) |
6-9 4-12 6-7 ~11 9-12 |
2-3 1-7.5 1-2 ~4 1-2 |
10-16 4-12 9-11 ~16.5 20-40 |
50-70 65-72 45-60 ~37 18-20 |
15-25 0 12-15 <1 0 |
1-6 3-15 15-19 ~23 20-40 |
Future prospects
Questions remain concerning the reasons which
have so far prevented a more extensive consumption of hemp seed oil. It is possible
that the historically significant uses of hemp (i.e., fibre, medicine, whole seed,
psychoactive drug) took priority over its potential utilisation as a source of oil.
Secondly, many other plant sources of oil have been found more adequate in terms of yield
and chemical stability of their oil, and the nutritional value of hemp seed oil was little
known. Finally, the relatively recent "anti-drug" ban on hemp cultivation
in many countries has prevented food scientists from investigating in more depth the wide
range of potential uses for this seed.
Probably no other single source of oil offers a more favorable human
dietary balance of the two essential fatty acids, LA and LNA. Even though hemp seed
oil contains only relatively small amounts of GLA when compared to more established
sources, this is probably sufficient for many of those who cannot efficiently convert LNA
to GLA, and helps to prevent GLA overconsumption. In addition, because of its ease
of cultivation, Cannabis may possess the potential to become an alternative raw
material source for the production of isolated forms of GLA as a special dietary
supplement.
Much work remains to be undertaken with the existing cultivars, as well
as indigenous landraces and feral strains. A major research priority must be the
full characterization of oils obtained from diverse hemp sources. There exists
considerable potential for development of varieties providing larger yields of seed
containing a higher oil content with a consistent fatty acid profile. Knowledge of
environmental influences on seed quality and the development of improved agricultural
methods will also contribute to the future success of this plant. In addition,
important questions remain concerning this oils physico-chemical properties,
triglyceride structures, and physiological effect, as well as the methods of extraction
and storage that are most economical and best suited to preserve its unique nutritional
qualities.
References