Clinical significance of Saussurea Costus in thyroid treatment

Saussurea costus (S. costus) synonymous with Saussurea lappa, also known as (نبات القسط أو القسط الهندي) qust in Arabic or Costus root in English, belongs to family of Asteraceae, a species of thistle in the genus Saussurea found worldwide mostly in Western Himalayan region of Pakistan and India. The growth of S. costus is limited to specific moist Himalayan region at altitude of 2600-4000m.1 The cultivation of S. costus for commercial purpose started in 1920s.2 Since ancient times, oils extracted from the root have been used in traditional medicines and perfumes.3 Saussurea costus is one of the therapeutic plants extensively used as a traditional medicine in Saudi Arabia.4

The medicinal properties of S. costus are well recognized in traditional systems of medicine including, Ayurvedic, Chinese, and Tibetan. The roots of S. costus are bitter in taste with strong aromatic odor and are believed to have anti-inflammatory, antimicrobial, analgesic, anti-ulcer, anticancer, and hepatoprotective properties in humans. Major constituents of this plant have potential to be developed as bioactive molecules. The costus oil (the oil extracted from the roots of S. costus) has been used in leprosy.5 Saussurea costus roots have also been used in many other medical conditions including chronic gastritis, stomach ulcers, rheumatoid arthritis, asthma and bronchitis in traditional medicine and in inflammation-related diseases. Saussurea costus is one of the most commercially used herbs in various indigenous systems of medicine.6 Data on possible role of S. costus in thyroid disorders are lacking. In this article, based on current available evidence, we summarize comprehensive analysis of the role of S. costus in thyroid disorders.

Basic details and therapeutic role of S. costus

Therapeutic role of S. costus in various conditions

Thyroid disorders and natural treatments

Worldwide, incidence of endocrine diseases including thyroid disorders is increasing. Thyroid disorders are generally classified into hyper and hypothyroidism. Women are more likely to have alteration in thyroid function as compared to men.21 In general, patients with thyroid disorders may have decreased circulating thyroid hormones (hypothyroidism) or increased levels of thyroid hormones (hyperthyroidism). Hypothyroidism is one of the most prevalent endocrine disorders characterized by low levels of thyroid hormones (T3 & T4) in the serum and high thyroid stimulating hormone (TSH). The common cause of hypothyroidism is autoimmune thyroiditis.22 The prevalence of hypothyroidism in the general population is variable ranging from 0.3% to 3.7% in the United States to 0.2% to 5.3% in European population.23-25 Approximately, 3% to 8% of world population have subclinical hypothyroidism, a condition with no apparent symptoms of thyroid hormone deficiency. The prevalence of overt hyperthyroidism is approximately 0.5% in both European and American population.24,25 In the Arab world, the prevalence of thyroid disorders ranges from 6.18% to 47.34%. The prevalence of goitre in Arabian countries has been reported to be 25% in Egypt and 1.7% in Bahrain.26 In comparison to other populations, the prevalence of thyroid dysfunction among Saudi adults has been reported to be higher. Gaffer et al27 reported an overall prevalence of 43.6% including 40.8% hypothyroidism and 2.8% as hyperthyroidism.27 Like in other countries, among all thyroid disorders, hypothyroidism has been reported to be the most prevalent among Arab population. Among Arabs, a considerably higher prevalence of hypothyroidism has been documented in Saudi population (43.3%) as compared to 6.18% in Libya.28 Currently, levothyroxine replacement is the choice of treatment in hypothyroidism. Although, it has been shown that in spite of being euthyroid, patients taking levothyroxine have decreased neurocognitive function and lead a suboptimal quality of life.29 Further, levothyroxine treatment is associated with poor compliance.30

Role of S. costus in thyroid disorders and other human disease and its side effects

The potential role of S. costus has been explored in the treatment of various diseases. In an animal study, S. costus root extract decreased sodium and calcium ions and reduced renal toxic effects caused by ethephon (2-chloroethylphosphonic acid), a plant growth promoter used to control the plant growth process.43 A study by Abd Eldaim et al44 showed protective effect of S. costus on ethephon induced reproductive toxicity in rats by ameliorating sperms abnormalities, testicular tissue and DNA damages, P53 protein expressions. Dehydrocostus lactone, a sesquiterpene from S. costus, suppresses allergic airway inflammation by binding to dimerized translationally controlled tumor protein, a protein involved in many allergic disorders.45 Sesquiterpene lactones from S. costus root extracts and semi synthetic sesquiterpene analogues play a role in tumor necrosis factor, an inflammatory cytokine inhibition.46

In-vitro study has shown that in hepatocellular carcinoma, the volatile oil from S. costus inhibits the epithelial growth factor receptor thyrosine kinase-mediated signalling pathway and exerts its antitumor effect.47 In a small human study Upadhyay et al48 showed that Aquous extract of S. costus improved clinical and biochemical parameters, coronary circulation and myocardial function in patients suffering from ischemic heart disease.

The role of S. costus has been explored in various endocrine diseases. In animal models, the alcoholic extract of the root of S. costus improved hypoglycemic response without increase in plasma insulin with initial accumulation of glycogen in the liver followed by its depletion. Its effect on the histology of thyroid gland was shown to be stimulatory, no toxic effect was observed in liver (on doses up to 400 mg/kg body weight) and no change was observed in adrenal gland and pancreas.49

Recently, a study in adult rats evaluated the effect of root extract of S. costus on thorium toxicity in brain also assessed the antioxidant effect and modulation activity of thyroid gland. Thorium accumulation caused disturbance in sodium and potassium ions and decrease in monoamines in brain also lead to oxidative stress which was evident by increased lipid peroxidation and decrease glutathione content. Thorium also increased thyroid-stimulating hormone (TSH), triiodothyronine (T3), and thyroxine (T4) levels. These effects of thorium were mitigated with prior oral administration of S. costus extract suggesting its protective effect mainly through its antioxidant mechanism.45 Antioxidant properties of various plant extracts may be an important mechanism involved in potentiating their medicinal use in various ailments.46

Renal, hepatic and lipid abnormalities are seen in thyroid dysfunction.50,51 Ethanoic extract of S. costus has shown hepatoprotective effect in rats, poisoned with carbon tetrachloride. Liver plays an important role in regulating metabolism of thyroid hormones and similarly thyroid hormones regulate liver function. A study showed that as compared to non-treated mice, treatment with S. costus root extract alleviated hyperthyroidism and hypothyroid induced hepatic enzymes derangements. The same study also revealed ameliorating effects of Costus extract on altered TSH, T4, sodium, potassium, chloride, albumin, creatinine, urea, calcium ions, cholesterol and triglycerides levels in hypo and hyperthyroid mice.52 Thyroid hormones may affect renal, electrolytes and mineral metabolism; however, the exact mechanism for these changes is not clear. Some authors have reported altered levels of electrolytes in hypo and hyperthyroidism whereas some contradicts this observation.53 Possibly due to altered metabolic clearance, cholesterol, low density lipoprotein (LDL) levels are increased in hypothyroidism. In a mice study, oral S. costus treatment normalized these lipid abnormalities by reducing plasma LDL cholesterol, possibly through increased LDL receptor activity.52 A study from Egypt by Sahar et al54 showed that a polyherb with S. costus “as one of its constituents at low doses” was effective in treating LT4 induced hyperthyroidism in rats and found it to be safer than anti thyroid drug Carbimazole and ameliorated most signalling pathways and in different tissues. These favorable effects of polyherb on thyroid gland may have been induced by flavonoids such as dillapiole, costunolide and caffeic acid by reducing thyroid peroxidase activity. These effects may be pronounced when iodine is deficient. Other flavonoids, such as kaempferol and quercetin, have also shown irreversible inhibitory effect on thyroid peroxidise activity. Additionally, Tannins like gallic acid and epigallocatechin gallate, which exhibit chelating effect through bonding with inorganic iodide might play a role in ameliorating hyperthyroidism.54 Another animal study by Han et al55 in Saudi Arabia assessed the protective effect of aqueous extract of S. costus and showed alleviating toxic effects of pesticide on thyroid gland function. Prior treatment by S. costus extract in pesticide intoxicated rats improved histomorphological changes in thyroid gland and up modulated thyroid hormones suggesting its protective effect against adverse impact of deltamethrin, a pesticide. This may be related to antioxidant activity of S. costus. As hypothyroidism may induce hyperlipidemia, the same study also revealed hypolipidemic effect of the extract of S. costus which may be linked to its favorable modulating impact on the thyroid hormones.4 Based on such observations, it was proposed that S. costus roots can be used as an adjuvant co-therapy to propylthiouracil and thyroxine treatment in hypo- and hyperthyroidism respectively.52 A schematic diagram of various biological effects of S. costus is shown in Figure 1.

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Figure 1

Schematic diagram of various biological effects of Saussurea costus.

Safety and side effects of S. costus

Not much information is available about safety and side effect profile of S. costus. Generally, S. costus root may be safe when taken appropriately by mouth but S. costus may contain a contaminant called aristolochic acid which may have nephrotoxic and carcinogenic effects.55 Safety of S. costus has not been ascertained in pregnant or breast-feeding women. Saussurea costus may cause an allergic reaction in those who are allergic to Saussurea species, their constituents including the sesquiterpene lactones (STL). Those exposed to STLs, have been observed to develop contact dermatitis. Concerns have been raised about their concerns regarding the genotoxic embryotoxic potential of these compounds. In vivo and vitro assays have reported mutagenic effect of STLs.56

In conclusion, natural therapies are not usually considered a part of standard care modern medicine which is evidence based. It has been envisaged to use natural therapies as a co treatment along with standard treatment speculating absence of side effects of natural treatments and in quest to do more to alleviate ones symptoms and improve health. Available data has shown some role of S. costus in the management thyroid disorders in animal models but has not been proven for clinical use. The current available evidence is inconclusive regarding thyrotropic activities of S. costus and its potential role in the management of thyroid disorders in humans. More research is needed quantify the effectiveness of S. costus for its use in thyroid disorders.