Psyllium: Wikis


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Psyllium plant (Plantago ovata)
Flower of Plantago ovata, commonly known as "blonde psyllium" and "isabgol".
Flower of Plantago arenaria
(syn.: P. psyllium L., P. indicia L. PLIN2,
P. scabra Moench), commonly known as "French" or "dark psyllium."
Not to be confused with Cilium. For the mucilaginous health product, see Psyllium seed husks.

Psyllium or Ispaghula is the common name used for several members of the plant genus Plantago whose seeds are used commercially for the production of mucilage.



The genus Plantago contains over 200 species. P. ovata and P. psyllium are produced commercially in several European countries, the former Soviet Union, Pakistan, and India. Plantago seed, known commercially as black, French, or Spanish psyllium, is obtained from P. psyllium L., also known as P. arenaria. Seed produced from P. ovata is known in trading circles as white or blonde psyllium, Indian plantago, or Isabgol. Isabgol, the common name in Pakistan and India for P. ovata, comes from the Persian words asb and ghol, meaning "horse flower," which is descriptive of the shape of the seed. India dominates the world market in the production and export of psyllium. Psyllium research and field trials in the U.S. have been conducted mainly in Arizona and Washington state.

Recent interest in psyllium has arisen primarily due to its use as an ingredient in high-fiber breakfast cereals, which is claimed to be effective in reducing blood cholesterol levels in those who consume it. Several studies point to a cholesterol reduction attributed to a diet that includes dietary fiber such as psyllium. Research reported in The American Journal of Clinical Nutrition concludes that the use of soluble-fiber cereals is an effective and well-tolerated part of a prudent diet for the treatment of mild to moderate hypercholesterolemia. Research also indicates that psyllium incorporated into food products is more effective at reducing blood glucose response than use of a soluble-fiber supplement that is separate from the food. Although the cholesterol-reducing and glycemic-response properties of psyllium-containing foods are fairly well documented, the effect of long-term inclusion of psyllium in the diet has not been determined. Cases of allergic reaction to psyllium-containing cereal have been documented.


Psyllium is mainly used as a dietary fiber, which is not absorbed by the small intestine. The purely mechanical action of psyllium mucilage absorbs excess water while stimulating normal bowel elimination. Although its main use has been as a laxative, it is more appropriately termed a true dietary fiber and as such can help reduce the symptoms of both constipation and mild diarrhea.

Psyllium is produced mainly for its mucilage content, which is highest in P. ovata. The term mucilage describes a group of clear, colorless, gelling agents derived from plants. The mucilage obtained from psyllium comes from the seed coat. Mucilage is obtained by mechanical milling/grinding of the outer layer of the seed. Mucilage yield amounts to about 25% (by weight) of the total seed yield. Plantago-seed mucilage is often referred to as husk, or psyllium husk. The milled seed mucilage is a white fibrous material that is hydrophilic, meaning that its molecular structure causes it to attract and bind to water. Upon absorbing water, the clear, colorless, mucilaginous gel that forms increases in volume by tenfold or more.

The United States is the world's largest importer of psyllium husk, with over 60% of total imports going to pharmaceutical firms for use in products such as "Metamucil". In Australia, psyllium husk is used to make "Bonvit" psyllium products. In the UK, ispaghula husk is used in the popular constipation remedy "Fybogel". In India, psyllium husk is used to make "Gulab Sat Isabgol" psyllium products. Psyllium mucilage is also used as a natural dietary fiber for animals. The dehusked seed that remains after the seed coat is milled off is rich in starch and fatty acids, and is used in India as chicken feed and as cattle feed.

Psyllium mucilage possesses several other desirable properties. As a thickener, it has been used in ice cream and frozen desserts. A 1.5% weight/volume ratio of psyllium mucilage exhibits binding properties that are superior to a 10% weight/volume ratio of starch mucilage. The viscosity of psyllium mucilage dispersions are relatively unaffected between temperatures of 20 and 50 °C (68 and 122 °F), by pH from 2 to 10 and by salt (sodium chloride) concentrations up to 0.15 M. These physical properties, along with its status as a natural dietary fiber, may lead to increased use of psyllium by the food-processing industry. Technical-grade psyllium has been used as a hydrocolloidal agent to improve water retention for newly-seeded grass areas, and to improve transplanting success with woody plants.

It is suggested that the isabgol husk is suitable carrier for the sustained release of drug and also used as gastroretentive carrier due to its swellable and floatable nature. The mucilage of isabgol used as super disintegrant in many formulations.

Growth habit

Plantago ovata is an annual herb that grows to a height of 30–46 cm (12–18 in). Leaves are opposite, linear or linear lanceolate 1 cm × 19 cm (0.39 in × 7.5 in). The root system has a well developed tap root with few fibrous secondary roots. A large number of flowering shoots arise from the base of the plant. Flowers are numerous, small, and white. Plants flower about 60 days after planting. The seeds are enclosed in capsules that open at maturity.

Environment requirements



P. ovata is a 119- to 130-day crop that responds well to cool, dry weather. In India, P. ovata is cultivated mainly in North Gujarat as a "Rabi" or post–rainy season crop (October to March). During this season, which follows the monsoons, average temperatures are in the range of 15–30 °C (59–86 °F), and moisture is deficient. Isabgol (P. ovata), which has a moderate water requirement, is given 5 to 6 light irrigations. A very important environmental requirement of this crop is clear, sunny and dry weather preceding harvest. High night temperature and cloudy wet weather close to harvest have a large negative impact on yield. Rainfall on the mature crop may result in shattering and therefore major field losses.


Isabgol grows best on light, well drained, sandy loams. The nutrient requirements of the crop are low. In North Gujarat, the soil tends to be low in nitrogen and phosphorus and high in potash with a pH between 7.2 and 7.9. Nitrogen trials under these conditions have shown a maximum seed yield response with the addition of 22 kg/hectare (20 lb/acre) of nitrogen.

Seed preparation and germination

P. ovata has small seeds; 1,000 seeds weigh less than 2 grams. Under ideal conditions of adequate moisture and low temperature 10 to 20 °C (50 to 68 °F), 30% of seeds germinate in 5 to 8 days. The seed shows some innate dormancy (3 months) following harvest. Attempts to eliminate this dormancy period by scarification, or by exposure to wet or dry heat, cold, ethylene, or carbon dioxide, are ineffective. Post-dormancy seeds show reliable germination in excess of 90% at 29 °C (84 °F), with lower rates of germination as temperature is increased.


The fields are generally irrigated prior to seeding to achieve ideal soil moisture, to enhance seed soil contact, and to avoid burying the seed too deeply as a result of later irrigations or rainfall. Maximum germination occurs at a seeding depth of 6 mm (1/4 in). Emerging seedlings are frost sensitive, therefore planting should be delayed until conditions are expected to remain frost free. Seed is broadcast at 5.5 to 8.25 kg/hectare (5 to 7.5 lb/acre) in India. In Arizona trials, seeding rates of 22 to 27.5 kg/ha (20 to 25 lb/acre) resulted in stands of 1 plant/25mm (1 inch) in 15 cm (6 inch) rows produced excellent yields. Weed control is normally achieved by one or two hand weedings early in the growing season. Control of weeds by pre-plant irrigation that germinates weed seeds followed by shallow tillage may be effective on fields with minimal weed pressure. Psyllium is a poor competitor with most weed species.

Plantago wilt "Fusarium oxyspirum" and downy mildew are the major diseases of Isabgol. White grubs and aphids are the major insect pests.

The flower spikes turn reddish brown at ripening, the lower leaves dry and the upper leaves yellow. The crop is harvested in the morning after the dew is gone to minimize shattering and field losses. In India, mature plants are cut 15 cm above the ground and then bound, left for a few days to dry, thrashed, and winnowing.

Harvested seed must be dried below 12% moisture to allow for cleaning, milling, and storage. Seed stored for future crops has shown a significant loss in viability after 2 years in storage.

Yield potential and performance results

The contract price for 95% purity psyllium husk set by the Indian Basic Chemical, Pharmaceutical and Cosmetic Export Promotion Council for April 1988 was $1.65/lb F.O.B. ($3.63/kg). This price is up from $1.14/lb ($2.51/kg) set in 1985. The average seed yield of P. ovata in India often exceeds 1 tonne/hectare (1000 lb/acre). Net yield of 95% purity husk after milling would be 275 kg/ha (250 lb/acre). Average gross revenue from milled product at 1988 prices would be $412/acre ($907/kg). The costs of production and milling in the U.S. are unknown but would certainly need to be determined in order to analyze the potential profitability of a commercial psyllium venture.

Economics of production and markets

The U.S. currently imports and consumes approximately 8,000 tonnes of psyllium annually. A continued expansion of this market seems likely due to the high level of interest in natural dietary fibers. No variety has been tested in the Upper Midwest but it would seem that the varieties that are grown in India would not be suited to production in this area. A major cultural problem limiting psyllium production in this area is the shattering characteristic of the mature crop. Some success has been achieved by cross-breeding high yielding Indian varieties with varieties that are more shatter resistant. Until shatter resistant varieties are available, production of Isabgol is likely to be restricted to environments that consistently provide a cool dry harvest season.

See also


  • Abraham, Z.D. and T. Mehta. 1988. Three-week psyllium husk supplementation: Effect on plasma cholesterol concentrations, fecal steroid excretion, and carbohydrate absorption in men. Am. J. Clin. Nutr. 47(1):67-74.
  • Anderson, J.R., K. Bukhave, L. Hojgaard, J. Rasmussen, N. Hermansen, H. Worning and E. Krag 1988. Decomposition of wheat bran and isabgol husk in the stomach and small intestine of healthy men. J. Nutr. 118(3):326-331.
  • Anderson, J.W., D. Deakins, T. Floore, B. Smith, S. Whitis. 1990. Dietary fiber and coronary heart disease. Crit. Rev. Food Sci. Nutr. 29(2):95-147.
  • Bell, L.P., K. Hectorn, H. Reynolds, D. Hunninghake. 1990. Cholesterol-lowering effects of soluble-fiber cereals as part of a prudent diet for patients with mild to moderate hypercholesterolemia. Am. J. Clin. Nutr. 52(6):1020-1026.
  • Bhagat, N.R. 1980. Studies on variation and association among seed yield and some component traits in Plantago ovata Forsk. Crop Improv. 7:60-63.
  • Chan, J.K.C. and V. Wypyszyk. 1988. A forgotten natural dietary fiber: psyllium mucilloid. Cereal Foods World 33(11):919-922.
  • Chastagner, G.A., J. Ogawa, K. Sammeta. 1978. Cause and control of damping off of Plantago ovata. Plant Disease Reporter 62:929-932.
  • Costa, M.A., T. Mehta, J. Males. 1989. Effects of dietary cellulose, psyllium husk and cholesterol level on fecal and colonic microbial metabolism in monkeys. J. Nutr. 119(7):986- 992.
  • Czarnecki, M. and L. Golez. 1987. Influence of mineral fertilization on yield and nutrient absorption in Plantago psyllium L. Herba Pol 31(3/4):167-174.
  • Gupta, R. 1982. Recent advances in cultivation of Isabgol (Plantago ovata Forsk.) in India. In Cultivation and Utilization of Medicinal Plants. C.K. Atal and B.M. Kapar eds. Pages 406- 417.
  • Lantner, R.R., B. Espiritu, P. Zumerchik, M. Tobin. 1990. Anaphylaxis following ingestion of a psyllium-containing cereal. J.A.M.A.J. Am. Med. Assoc. 264(19):2534-2536.
  • Liebman, B. 1988. The laxative that lowers cholesterol. Nutr. Action Health Letter 15(9):9.
  • Mathur, D.P., B. Rangarajan, V. Gupta. 1990. Psyllium production and marketing in India. New Delhi: Oxford and IBH Pub. Co. 167 pp.
  • McNeil, D.L. 1989. Factors affecting the field establishment of Plantago ovata Forsk. in northern Australia. Trop. Agric. 66(1):61-64.
  • Jain, Manoj Kumar,1976. Psyllium. Ahmedabad, India (91) 93749 78709.
  • Modi, S.M., K. Mehta, and R. Gupta. 1974. Isabgol, a dollar earner of North Gujarat. Indian Farming 23(10):17-19.
  • Psyasyatskene, A.A. and Y. Vaichyunene. 1987. Plantains in the Lithuanian S.S.R.: Specific growth of local species and species being introduced and mucilage localization in their organs. I. in Russian: Abstract in English in Hort Abstracts.
  • Rubis, D.D. 1990. Personal communique in regard to Plantago and psyllium.
  • Russell, T.E. 1975. Plantago wilt. Phytopathology 65:359-360.
  • Samra, J.S. and B. Gill. 1986. Seed yield of Isabgol as influenced by doses and sources of nitrogen. J. Res. Punjab Agric. Univ. 23(4):557-560.
  • Stewart, R.B., W. Jale, M. Moore, F. May, R. Marks. 1991. Effect of psyllium hydrophilic mucilloid on serum cholesterol in the elderly. Dig. Dis. Sci. 36(3):329-334.
  • The Herb Market Report. 1990. anon. 6(1).
  • Wolever, T.M.S., V. Vuksan, H. Eshuis, P. Spafadora, R. Peterson, E. Chao, M. Storey, and D. Jenkins. 1991. Effect of method of administration of psyllium on glycemic response and carbohydrate digestibility. J. Am. Coll. Nutr. 10(4):364-371.

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