Skip to main content

Senega Root

Scientific Name(s): Polygala senega L.
Common Name(s): Milkwort, Mountain flax, Polygalae radix, Rattlesnake root, Seneca snakeroot, Tenuigenin

Medically reviewed by Drugs.com. Last updated on Dec 11, 2023.

Clinical Overview

Use

Senega has been traditionally used as an antitussive and has also demonstrated hypoglycemic, immunologic, and anticancer effects. However, there are no clinical trials to support these uses.

Dosing

Root: 1 to 3 g/day. Fluid extract: 1.5 to 3 g/day or 0.3 to 1 mL/day. Tincture: 2.5 to 7.5 g/day or 2.5 to 5 mL/day.

Contraindications

Pregnancy, peptic ulcer disease, or inflammatory bowel disease.

Pregnancy/Lactation

Avoid use. Emmenagogue and uterine stimulant action has been documented.

Interactions

None well documented.

Adverse Reactions

High doses of powdered senega root or tincture are emetic and irritating to the GI tract.

Toxicology

When investigated for their immunological potential as adjuvants in vaccinations, saponin fractions of P. senega were less toxic than those of Quillaja saponaria.

Scientific Family

Botany

Senega root is an uncommon perennial herb found throughout eastern North America(van Wyk 2004); it has "endangered" status in Connecticut, Maine, and New Jersey and "threatened" status in Maryland.(USDA 2016) The plant grows to approximately 0.5 m in height and has unbranched stems arising from a branched root.(van Wyk 2004, WHO 2004) The leaves are small, alternate, and narrowly lanceolate. Numerous pinkish-white or greenish-white flowers are crowded on a terminal spike. The root is twisted and has an irregular, knotty crown with a distinctive ridge. Senega's faint, sweet scent is similar to that of methyl salicylate.(WHO 2004) The variety P. senega var. latifolia Torr. & Gray has been distinguished; it grows in the same habitat but differs from P. senega in the size of its leaves and flowers and in its slightly later flowering period. Related species include Polygala tenuifolia Willd., Polygala reinii Franch., Polygala glomerata Lour., and Polygala japonica Houtt., all of which are used in Asia in a similar manner to P. senega.

History

Senega root was used by eastern American Indian tribes, including the Seneca tribe (from whom its name is derived), to treat rattlesnake bites(van Wyk 2004); however, early European observers gave little credence to this use. Colonists and Europeans used senega root as an emetic, cathartic, diuretic, and diaphoretic, and in treatment of pulmonary diseases (such as pneumonia, asthma, and pertussis), gout, and rheumatism.(Erichsen-Brown 1979) Its main use in the 19th century was as an expectorant cough remedy. It was included in the US Pharmacopeia from 1820 to 1936 and in the National Formulary from 1936 to 1960.

Chemistry

Seneca snakeroot contains a series of saponins constructed from the 2,3,27-trihydroxy-oleanane 23,28-dioic acid triterpene skeleton (presenegenin), with a single sugar attached at position 3 and a 4- to 6-sugar chain appended at position 28. A variety of methoxy-cinnamate esters are attached at the internal sugar of the C-28 chain.(Akada 1971, Shoji 1971, Shoji 1971, Shoji 1972, Tsukitani 1973, Yoshikawa 1995, Yoshikawa 1996, Yoshikawa 1995) These saponins have been named senegins Ι through ΙV and senegasaponins A through C. The triterpene senegenin, also known as tenuigenin, is considered a major bioactive compound. The senegins can be analyzed by high-performance liquid chromatography.(Kanazawa 1993, Lacaille-Dubois 2020) Several other species of Polygala (see Botany) contain distinct but very similar saponins based on the same sapogenin.(Zhang 1998) An extensive series of ester oligosaccharides, senegoses A through O, have been isolated from P. senega var. latifolia.(Saitoh 1993, Saitoh 1993, Saitoh 1994) The root also contains a small amount of methyl salicylate, which is responsible for its characteristic wintergreen scent.

Uses and Pharmacology

Antitussive effects

The antitussive effect of senega root has generally been attributed to the saponin content of the plant, which is consistent with the general detergent property of saponins in breaking up phlegm.(van Wyk 2004) In addition, senega is thought to act by irritation of the gastric mucosa followed by a reflex action, which stimulates an increase in bronchial mucous gland secretion. However, most of the available information about senega's antitussive properties is anecdotal.

Animal and in vitro data

In a study of anesthetized dogs, senega syrup dosed orally at 3 mL/kg (about 90 mg/kg) increased the volume output of respiratory tract fluid within 5 minutes of administration; the increase continued at 30 minutes following administration.(Misawa 1980)

Clinical data

In one study, a fluid extract of senega root reduced mucus viscosity in patients with bronchiectasis.(WHO 2004)

Cancer

Animal and in vitro data

In mice inoculated with sarcoma S180 cells, the senega saponin senegin III dosed at 2.5 mg/kg inhibited tumor growth in a manner similar to cisplatin. In addition, the combination of senegin III with cisplatin resulted in greater growth inhibition compared with the control group.(Arai 2011)

In in vitro and an in vivo models in mice, P. senega was beneficial in the treatment of lung cancer. Administration of senega 50 and 100 mg/kg in mice with long-term exposure to a carcinogen modulated the expression of signal proteins.(Paul 2010) Similarly, an ethanolic root extract of P. senega reduced DNA damage as well as tumor nodules and tumor growth in mice with benzo[a]pyrene-induced lung cancer.(Paul 2011) Nanoencapsulation of an ethanolic root extract of P. senega was associated with greater inhibition of cancer cell growth, better bioavailability, and increased cellular entry compared with the non-nanoencapsulated ethanolic root extract of P. senega.(Paul 2011)

Hypoglycemic effects

Animal and in vitro data

In studies evaluating the hypoglycemic effects of senega saponins in mice with and without diabetes, hypoglycemic activity was observed in normal and diabetic mice, but not in mice with streptozotocin-induced diabetes.(Kako 1995, Kako 1996, Kako 1997, Yoshikawa 1995, Yoshikawa 1995, Yoshikawa 1996) Thus, these compounds have activity relevant to non–insulin-dependent diabetes. This activity is most potent when the saponins are injected intraperitoneally but can also be detected with higher oral doses. The same saponins also substantially reduced alcohol absorption when given orally to rats 1 hour before alcohol consumption.(Yoshikawa 1995, Yoshikawa 1996, Yoshikawa 1995)

In a study investigating an aqueous extract of the related species P. tenuifolia, a potent blocking effect on inflammatory processes in cultured mouse astrocytes was observed. Substance P– and lipopolysaccharide-induced production of tumor necrosis factor and interleukin-1 (IL-1) was blocked by a P. tenuifolia extract at low concentrations.(Kim 1998) It is possible that a systemic anti-inflammatory effect may be the result of a similar mechanism.

No biological activity has been reported for the oligosaccharides of senega root. Senegose A was inactive in the previously described hypoglycemia model.(Kako 1997)

Immunological effects

Animal and in vitro data

In a murine model, P. senega saponins increased antibody response to ovalbumin antigens in mice. These effects were similar to those of saponins from Q. saponaria but were less toxic, suggesting a potential role as an adjuvant in vaccines.(Katselis 2007) Another study demonstrated similar effects in mice immunized with ovalbumin, with no P. senega saponin effect detected 10 days after immunization; in another arm of this study, P. senega saponins increased the immunoglobulin G response to rotavirus in immunized hens.(Estrada 2000) In an in vitro study, senega saponins exerted antiangiogenic activity against human umbilical vein endothelial cells.(Arai 2011)

A cell-screening assay of several P. senega extracts revealed dose-dependent anti-inflammatory effects, such as reductions in levels of IL-1beta, IL-6, and tumor necrosis factor alpha.(Van 2009)

Other uses

Tenuigenin, the major active component of P. senega and other Polygala species, has been shown to be a significant inhibitor of NF-kappaB and capable of preventing IL-1beta-induced inflammation in human osteoarthritis chondrocytes. Significant decreases in many other pro-inflammatory cytokines (ie, TNF-alpha, IL-1beta, IL-6, IL-12, PGE-2) and enzymes (ie, iNOS, COX-2) have also been observed with tenuigenin, P. japonica, P. sabulosa, P. molluginifolia, and other species. Findings in animal models of neuroinflammation, pleurisy, peritonitis, pneumonia, liver, and kidney injury further support the anti-inflammatory effects of Polygala species and extracts.(Lacaille-Dubois 2020)

Neuroprotection against degeneration of dopaminergic neurons in a mouse model of Parkinson disease was documented for tenuigenin, which also improved neuroplasticity in vitro by potentiating basic synaptic transmission via regulation of presynaptic intracellular calcium. In an Alzheimer murine model, tenuigenin significantly improved memory-related behaviors and cognitive dysfunction via dose-dependent antioxidant effects in the hippocampus. Improvements in memory and cognitive function were also demonstrated with tenuigenin in a menopausal mouse model.(Lacaille-Dubois 2020)

Dosing

Root

1 to 3 g/day.(Blumenthal 1998, Claus 1956)

Fluid extract

1.5 to 3 g/day(Brinker 1998) or 0.3 to 1 mL/day.(van Wyk 2004)

Tincture

2.5 to 7.5 g/day(Blumenthal 1998) or 2.5 to 5 mL/day.(van Wyk 2004)

Pregnancy / Lactation

Avoid use. Emmenagogue and uterine stimulant action has been documented.(Brinker 1998, Ernst 2002)

Interactions

None well documented.

Adverse Reactions

High doses of powdered senega root (more than 1 g) or tincture are emetic and irritating to the GI tract.(Blumenthal 1998) The use of senega root is contraindicated during pregnancy, and in peptic ulcer disease or inflammatory bowel disease.(Grieve 1931) Senega may exacerbate inflammatory conditions of the GI tract.

Toxicology

When investigated for their immunological potential as adjuvants in vaccinations, saponin fractions of P. senega were less toxic than those from Q. saponaria, which have traditionally been used as adjuvants for veterinary vaccines.(Estrada 2000)

Index Terms

References

Disclaimer

This information relates to an herbal, vitamin, mineral or other dietary supplement. This product has not been reviewed by the FDA to determine whether it is safe or effective and is not subject to the quality standards and safety information collection standards that are applicable to most prescription drugs. This information should not be used to decide whether or not to take this product. This information does not endorse this product as safe, effective, or approved for treating any patient or health condition. This is only a brief summary of general information about this product. It does NOT include all information about the possible uses, directions, warnings, precautions, interactions, adverse effects, or risks that may apply to this product. This information is not specific medical advice and does not replace information you receive from your health care provider. You should talk with your health care provider for complete information about the risks and benefits of using this product.

This product may adversely interact with certain health and medical conditions, other prescription and over-the-counter drugs, foods, or other dietary supplements. This product may be unsafe when used before surgery or other medical procedures. It is important to fully inform your doctor about the herbal, vitamins, mineral or any other supplements you are taking before any kind of surgery or medical procedure. With the exception of certain products that are generally recognized as safe in normal quantities, including use of folic acid and prenatal vitamins during pregnancy, this product has not been sufficiently studied to determine whether it is safe to use during pregnancy or nursing or by persons younger than 2 years of age.

Akada Y, Yuki H, Takiura K. Studies on glycon moiety of Senega saponins. I. Isolation and purification of the Senega saponins [in Japanese]. Yakugaku Zasshi. 1971;91(11):1178-1181.5169124
Arai M, Hayashi A, Sobou M, et al. Anti-angiogenic effect of triterpenoidal saponins from Polygala senega.J Nat Med. 2011;65(1):149-156.21042868
Blumenthal M, Busse WR, eds. 1st ed. The Complete German Commission E Monographs: Therapeutic Guide to Herbal Medicines. Austin, TX: American Botanical Council; Boston, MA: Integrative Medicine Communications; 1998.
Brinker FJ. Herb Contraindications and Drug Interactions. 2nd ed. Sandy, OR: Eclectic Medical Publications; 1998.
Claus E, ed. Pharmacognosy. 3rd ed. Philadelphia, PA: Lea & Febiger; 1956.
Erichsen-Brown C. Medicinal and Other Uses of North American Plants. Dover, NY: Dover Publications; 1979:359-362.
Ernst E. Herbal medicinal products during pregnancy: are they safe? BJOG. 2002;109(3):227-235.11950176
Estrada A, Katselis GS, Laarveld B, Barl B. Isolation and evaluation of immunological adjuvant activities of saponins from Polygala senega L. Comp Immunol Microbiol Infect Dis. 2000;23(1):27-43.10660256
Kako M, Miura T, Nishiyama Y, Ichimaru M, Moriyasu M, Kato A. Hypoglycemic activity of some triterpenoid glycosides. J Nat Prod. 1997:60(6):604-605.9214731
Kako M, Miura T, Nishiyama Y, Ichimaru M, Moriyasu M, Kato A. Hypoglycemic effect of the rhizomes of Polygala senega in normal and diabetic mice and its main component, the triterpenoid glycoside senegin-II. Planta Med. 1996;62(5):440-443.8923811
Kako M, Miura T, Usami M, et al. Effect of senegin-II on blood glucose in normal and NIDDM mice. Biol Pharm Bull. 1995;18(8):1159-1161.8535417
Kanazawa H, Nagata Y, Matsushima Y, Tomoda M, Takai N. Determination of acidic saponins in crude drugs by high-performance liquid chromatography on octadecylsilica porous glass. J Chromatogr. 1993;630(1-2):408-414.8445006
Katselis GS, Estada A, Gorecki DK, Barl B. Adjuvant activities of saponins from the root of Polygala senega L. Can J Physiol Pharmacol. 2007;85(11):1184-1194.18066120
Kim HM, Lee EH, Na HJ, et al. Effect of Polygala tenuifolia root extract on the tumor necrosis factor-alpha secretion from mouse astrocytes. J Ethnopharmacol. 1998;61(3):201-208.9705011
Lacaille-Dubois MA, Delaude C, Mitaine-Offer AC. A review on the phytopharmacological studies of the genus Polygala. J Ethnopharmacol. 2020;249:112417.31765761
Misawa M, Yanaura S. Continuous determination of tracheobronchial secretory activity in dogs. Jpn J Pharmacol. 1980;30(2):221-229.7452972
Paul S, Bhattacharyya SS, Boujedaini N, Khuda-Bukhsh AR. Anticancer potentials of root extract of Polygala senega and its PLGA nanoparticles-encapsulated form. Evid Based Complement Alternat Med. 2011;2011.20953431
Paul S, Bhattacharyya SS, Samaddar A, Boujedaini N, Khuda-Bukhsh AR. Anticancer potentials of root extract of Polygala senega against benzo[a]pyrene-induced lung cancer in mice. Zhong Xi Yi Jie He Xue Bao. 2011;9(3):320-327.21419086
Paul S, Mandal SK, Bhattacharyya SS, Boujedaini N, Khuda-Bukhsh AR. In vitro and in vivo studies demonstrate anticancer property of root extract of Polygala senega.J Acupunct Meridian Stud. 2010;3(3):188-196.20869020
Polygala senega L. USDA, NRCS. 2016. The PLANTS Database (http://plants.usda.gov, 21 September 2016). National Plant Data Team, Greensboro, NC 27401-4901 USA. Accessed September 21, 2016.
Radix Senegae. In: WHO Monographs on Selected Medicinal Plants. Vol. 2. Geneva: World Health Organization; 2004. http://apps.who.int/medicinedocs/en/d/Js4927e/27.html. Accessed September 23, 2016.
Saitoh H, Miyase T, Ueno A. Senegoses A-E, oligosaccharide multi-esters from Polygala senega var. latifolia Torr. et Gray. Chem Pharm Bull (Tokyo). 1993;41(6):1127-1131.8370112
Saitoh H, Miyase T, Ueno A. Senegoses F-I, oligosaccharide multi-esters from the roots of Polygala senega var. latifolia Torr. et Gray. Chem Pharm Bull (Tokyo). 1993;41(12):2125-2128.8118905
Saitoh H, Miyase T, Ueno A, Atarashi K, Saiki Y. Senegoses J-O, oligosaccharide multi-esters from the roots of Polygala senega L. Chem Pharm Bull (Tokyo). 1994;42(3):641-645.8004714
Senega. In: Grieve M. A Modern Herbal. 1931. Accessed January 30, 2016. http://www.botanical.com/botanical/mgmh/s/senega41.html.
Shoji J, Kawanishi S, Tsukitani Y. On the structure of senegin-ΙΙ of Senegae Radix. Chem Pharm Bull (Tokyo). 1971;19(8):1740-1742.
Shoji J, Kawanishi S, Tsukitani Y. Studies on the constituents of Senegae radix. Ι. Isolation and qualitative analysis of the glycosides [in Japanese]. Yakugaku Zasshi. 1971;91(2):198-202.5102349
Shoji J, et al. Structure of senegin-ΙΙΙ of Polygala senega root. Chem Pharm Bull. 1972;20:424.
Tsukitani Y, et al. Constituents of Senegae Radix. ΙΙΙ. Structures of senegin-III and -IV, saponins from Polygala senega var. latifolia. Chem Pharm Bull (Tokyo). 1973;21:1564.
Van Q, Nayak BN, Reimer M, Jones PJ, Fulcher RG, Rempel CB. Anti-inflammatory effect of Inonotus obliquus, Polygala senega L., and Viburnum trilobum in a cell screening assay. J Ethnopharmacol. 2009;125(3):487-493.19577624
van Wyk BE, Wink M, eds. Medicinal Plants of the World: an Illustrated Scientific Guide to Important Medicinal Plants and Their Uses. 1st ed. Portland, OR: Timber Press Inc; 2004.
Yoshikawa M, Murakami T, Ueno T, et al. Bioactive saponins and glycosides. I. Senegae radix. (1): E-senegasaponins a and b and Z-senegasaponins a and b, their inhibitory effect on alcohol absorption and hypoglycemic activity. Chem Pharm Bull (Tokyo). 1995;43(12):2115-2122.8582013
Yoshikawa M, Murakami T, Matsuda H, et al. Bioactive saponins and glycosides. II. Senegae Radix. (2): Chemical structures, hypoglycemic activity, and ethanol absorption-inhibitory effect of E-senegasaponin c, Z-senegasaponin c, and Z-senegins II, III, IV. Chem Pharm Bull (Tokyo). 1996;44(7):1305-1313.8706138
Yoshikawa M, Murakami T, Ueno T, et al. E-senegasaponins A and B, Z-senegasaponins A and B, Z-senegins II and III, new type inhibitors of ethanol absorption in rats from senegae radix, the roots of Polygala senega L. var. latifolia Torrey et Gray. Chem Pharm Bull (Tokyo). 1995;43(2):350-352.7728939
Zhang D, Miyase T, Kuroyanagi M, Umehara K, Noguchi H. Polygalasaponins XLII-XLVI from roots of Polygala glomerata. Phytochemistry. 1998;47(3):459-466.9433820

Further information

Always consult your healthcare provider to ensure the information displayed on this page applies to your personal circumstances.

Medical Disclaimer

Copyright © 2024 Wolters Kluwer Health