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Also known as Asian or Chinese lizard’s tail (or Sam-baekcho in Korea), Saururus chinensis is an East Asian plant used in traditional medicine for various indications including edema, gonorrhea, jaundice, hypertension, leproma, pneumonia, and rheumatoid arthritis.1,2 Specifically, Korean traditional medicine practitioners as well as Native Americans and early colonists in what is now the United States used the botanical to treat cancer, edema, rheumatoid arthritis, and other inflammatory conditions.2-4 Modern research has produced evidence supporting the use of this plant in the dermatologic realm. This column focuses on the relevant bench science and possible applications.
Various beneficial effects
In 2008, Yoo et al. found that the ethanol extract of the dried aerial parts of S. chinensis exhibit anti-inflammatory, antiangiogenic, and antinociceptive properties, which they suggested may partially account for the established therapeutic effects of the plant.2 Also, Lee et al. reported in 2012 on the antiproliferative effects against human cancer cell lines of neolignans found in S. chinensis.5
Antioxidant properties have been associated with S. chinensis. In 2014, Kim et al. reported that S. chinensis extract attenuated the lipopolysaccharide (LPS)-stimulated neuroinflammatory response in BV-2 microglia cells, a result that the authors partly ascribed to the antioxidant constituents (particularly quercetin) of the plant.3
Atopic dermatitis
In 2008, Choi et al. determined that the leaves of S. chinensis impeded the formation of atopic dermatitis–like skin lesions in NC/Nga mice caused by repeated application of picryl chloride, potentially by stimulating the Th1 cell response, thus modulating Th1/Th2 imbalance. They concluded that S. chinensis has potential as an adjunct treatment option for atopic dermatitis.6
Anti-inflammatory activity
In 2010, Bae et al. studied the anti-inflammatory properties of sauchinone, a lignan derived from S. chinensis reputed to exert antioxidant, anti-inflammatory, and hepatoprotective activity,7 using LPS-stimulated RAW264.7 cells. They found that the lignan lowered tumor necrosis factor (TNF)–alpha synthesis by inhibiting the c-Raf-MEK1/2-ERK1/2 phosphorylation pathway, accounting for the anti-inflammatory effects of the S. chinensis constituent.8
More recently, Zhang et al. determined that the ethanol extract of S. chinensis leaves impaired proinflammatory gene expression by blocking the TAK1/AP-1 pathway in LPS-treated RAW264.7 macrophages. They suggested that such suppression is a significant step in the anti-inflammatory function exhibited by the plant.1
Photoprotection
Park et al. investigated in 2013 the beneficial effects of sauchinone. Specifically, they studied potential photoprotective effects of the lignan against UVB in HaCaT human epidermal keratinocytes. They found that sauchinone (5-40 mcm) conferred significant protection as evaluated by cell viability and a toxicity assay. At 20-40 mcm, sauchinone blocked the upregulation of matrix metalloproteinase (MMP)–1 proteins and decrease of type 1 collagen engendered by UVB exposure. The investigators further discovered that sauchinone diminished the synthesis of reactive oxygen species. Overall, they determined that sauchinone imparted protection by suppressing extracellular signal-regulated kinase, c-Jun N-terminal kinase, and p38 MAPK signaling through the activation of oxidative defense enzymes.7
Potential use as a depigmenting agent
In 2009, Seo et al. isolated the lignans manassantin A and B from S. chinensis and determined that these compounds dose-dependently impeded melanin synthesis in alpha-melanocyte stimulating hormone (alpha-MSH)–activated melanoma B16 cells. They also noted that manassantin A suppressed forskolin- or 3-isobutyl-1-methylxanthine (IBMX)–induced melanin production and diminished cellular levels of IBMX-inducible tyrosinase protein. The lignan had no effect on the catalytic activity of cell-free tyrosinase, an important enzyme in melanin pigment production. The researchers concluded that their results suggest the potential for S. chinensis to be used to treat hyperpigmentation disorders.9
Two years later Lee et al. found that manassantin A, derived from S. chinensis, steadily suppressed the cAMP elevator IBMX- or dibutyryl cAMP-induced melanin synthesis in B16 cells or in melan-a melanocytes by down-regulating the expression of tyrosinase or the TRP1 gene. The lignan also inhibited microphthalmia-associated transcription factor (MITF) induction via the IBMX-activated cAMP-responsive element-binding protein (CREB) pathway, thus preventing the Ser-133 phosphorylation of CREB. The researchers concluded that this molecular disruption of melanin production suggests the potential for the use of manassantin A as a skin depigmenting agent.10
That same year, another S. chinensis lignan gained interest. Yun et al. investigated the effects of the S. chinensis lignan component saucerneol D on melanin synthesis in cAMP-elevated melanocytes. They found that the lignan efficiently impeded melanin product in B16 melanoma cells stimulated with alpha-MSH or other cAMP elevators. Saucerneol D was also credited with down-regulating alpha-MSH–induced gene expression of tyrosinase at the transcription level in B16 cells, suppressing alpha-MSH–induced phosphorylation of CREB in the cells, and inhibiting MITF induction. The investigators concluded that their results point to the potential of the S. chinensis lignan saucerneol D for the treatment of hyperpigmentation disorders.11
In 2012, Chang et al. observed that an extract of S. chinensis and one of its constituent lignans, manassantin B, prevented melanosome transport in normal human melanocytes and Melan-a melanocytes, by interrupting the interaction between melanophilin and myosin Va. The investigators concluded that as a substance that can hinder melanosome transport, manassantin B displays potential for use as depigmenting product.12
The following year, Lee et al. studied the effects of S. chinensis extracts on the melanogenesis signaling pathway activated by alpha-MSH, finding dose-dependent inhibition without provoking cytotoxicity in B16F10 cells. Further, the team found evidence that the depigmenting activity exhibited by S. chinensis extracts may occur as a result of MITF and tyrosinase expression stemming from elevated activity of extracellular signal-regulated kinase (ERK). They concluded that their results support further examination of S. chinensis for its potential to contribute to skin whitening.5
Conclusion
Multiple lignan constituents in this plant-derived ingredient appear to yield anti-inflammatory, antioxidant, photoprotective, and antitumor properties. Its inhibitory effects on melanin production and its antiaging abilities make it worthy of further study and consideration of inclusion in antiaging skin care products.
Dr. Baumann is a private practice dermatologist, researcher, author, and entrepreneur in Miami. She founded the division of cosmetic dermatology at the University of Miami in 1997. The third edition of her bestselling textbook, “Cosmetic Dermatology,” was published in 2022. Dr. Baumann has received funding for advisory boards and/or clinical research trials from Allergan, Galderma, Johnson & Johnson, and Burt’s Bees. She is the CEO of Skin Type Solutions, a SaaS company used to generate skin care routines in the office and as an e-commerce solution. Write to her at [email protected].
References
1. Zhang J et al. J Ethnopharmacol. 2021 Oct 28;279:114400.
2. Yoo HJ et al. J Ethnopharmacol. 2008 Nov 20;120(2):282-6.
3. Kim BW et al. BMC Complement Altern Med. 2014 Dec 16;14:502.
4. Lee DH et al. Biol Pharm Bull. 2013;36(5):772-9.
5. Lee YJ et al. Biol Pharm Bull. 2012;35(8):1361-6.
6. Choi MS et al. Biol Pharm Bull. 2008 Jan;31(1):51-6.
7. Park G et al. Biol Pharm Bull. 2013;36(7):1134-9.
8. Bae HB et al. Int Immunopharmacol. 2010 Sep;10(9):1022-8.
9. Seo CS et al. Phytother Res. 2009 Nov;23(11):1531-6.
10. Lee HD et al. Exp Dermatol. 2011 Sep;20(9):761-3.
11. Yun JY et al. Arch Pharm Res. 2011 Aug;34(8):1339-45.
12. Chang H et al. Pigment Cell Melanoma Res. 2012 Nov;25(6):765-72.
Also known as Asian or Chinese lizard’s tail (or Sam-baekcho in Korea), Saururus chinensis is an East Asian plant used in traditional medicine for various indications including edema, gonorrhea, jaundice, hypertension, leproma, pneumonia, and rheumatoid arthritis.1,2 Specifically, Korean traditional medicine practitioners as well as Native Americans and early colonists in what is now the United States used the botanical to treat cancer, edema, rheumatoid arthritis, and other inflammatory conditions.2-4 Modern research has produced evidence supporting the use of this plant in the dermatologic realm. This column focuses on the relevant bench science and possible applications.
Various beneficial effects
In 2008, Yoo et al. found that the ethanol extract of the dried aerial parts of S. chinensis exhibit anti-inflammatory, antiangiogenic, and antinociceptive properties, which they suggested may partially account for the established therapeutic effects of the plant.2 Also, Lee et al. reported in 2012 on the antiproliferative effects against human cancer cell lines of neolignans found in S. chinensis.5
Antioxidant properties have been associated with S. chinensis. In 2014, Kim et al. reported that S. chinensis extract attenuated the lipopolysaccharide (LPS)-stimulated neuroinflammatory response in BV-2 microglia cells, a result that the authors partly ascribed to the antioxidant constituents (particularly quercetin) of the plant.3
Atopic dermatitis
In 2008, Choi et al. determined that the leaves of S. chinensis impeded the formation of atopic dermatitis–like skin lesions in NC/Nga mice caused by repeated application of picryl chloride, potentially by stimulating the Th1 cell response, thus modulating Th1/Th2 imbalance. They concluded that S. chinensis has potential as an adjunct treatment option for atopic dermatitis.6
Anti-inflammatory activity
In 2010, Bae et al. studied the anti-inflammatory properties of sauchinone, a lignan derived from S. chinensis reputed to exert antioxidant, anti-inflammatory, and hepatoprotective activity,7 using LPS-stimulated RAW264.7 cells. They found that the lignan lowered tumor necrosis factor (TNF)–alpha synthesis by inhibiting the c-Raf-MEK1/2-ERK1/2 phosphorylation pathway, accounting for the anti-inflammatory effects of the S. chinensis constituent.8
More recently, Zhang et al. determined that the ethanol extract of S. chinensis leaves impaired proinflammatory gene expression by blocking the TAK1/AP-1 pathway in LPS-treated RAW264.7 macrophages. They suggested that such suppression is a significant step in the anti-inflammatory function exhibited by the plant.1
Photoprotection
Park et al. investigated in 2013 the beneficial effects of sauchinone. Specifically, they studied potential photoprotective effects of the lignan against UVB in HaCaT human epidermal keratinocytes. They found that sauchinone (5-40 mcm) conferred significant protection as evaluated by cell viability and a toxicity assay. At 20-40 mcm, sauchinone blocked the upregulation of matrix metalloproteinase (MMP)–1 proteins and decrease of type 1 collagen engendered by UVB exposure. The investigators further discovered that sauchinone diminished the synthesis of reactive oxygen species. Overall, they determined that sauchinone imparted protection by suppressing extracellular signal-regulated kinase, c-Jun N-terminal kinase, and p38 MAPK signaling through the activation of oxidative defense enzymes.7
Potential use as a depigmenting agent
In 2009, Seo et al. isolated the lignans manassantin A and B from S. chinensis and determined that these compounds dose-dependently impeded melanin synthesis in alpha-melanocyte stimulating hormone (alpha-MSH)–activated melanoma B16 cells. They also noted that manassantin A suppressed forskolin- or 3-isobutyl-1-methylxanthine (IBMX)–induced melanin production and diminished cellular levels of IBMX-inducible tyrosinase protein. The lignan had no effect on the catalytic activity of cell-free tyrosinase, an important enzyme in melanin pigment production. The researchers concluded that their results suggest the potential for S. chinensis to be used to treat hyperpigmentation disorders.9
Two years later Lee et al. found that manassantin A, derived from S. chinensis, steadily suppressed the cAMP elevator IBMX- or dibutyryl cAMP-induced melanin synthesis in B16 cells or in melan-a melanocytes by down-regulating the expression of tyrosinase or the TRP1 gene. The lignan also inhibited microphthalmia-associated transcription factor (MITF) induction via the IBMX-activated cAMP-responsive element-binding protein (CREB) pathway, thus preventing the Ser-133 phosphorylation of CREB. The researchers concluded that this molecular disruption of melanin production suggests the potential for the use of manassantin A as a skin depigmenting agent.10
That same year, another S. chinensis lignan gained interest. Yun et al. investigated the effects of the S. chinensis lignan component saucerneol D on melanin synthesis in cAMP-elevated melanocytes. They found that the lignan efficiently impeded melanin product in B16 melanoma cells stimulated with alpha-MSH or other cAMP elevators. Saucerneol D was also credited with down-regulating alpha-MSH–induced gene expression of tyrosinase at the transcription level in B16 cells, suppressing alpha-MSH–induced phosphorylation of CREB in the cells, and inhibiting MITF induction. The investigators concluded that their results point to the potential of the S. chinensis lignan saucerneol D for the treatment of hyperpigmentation disorders.11
In 2012, Chang et al. observed that an extract of S. chinensis and one of its constituent lignans, manassantin B, prevented melanosome transport in normal human melanocytes and Melan-a melanocytes, by interrupting the interaction between melanophilin and myosin Va. The investigators concluded that as a substance that can hinder melanosome transport, manassantin B displays potential for use as depigmenting product.12
The following year, Lee et al. studied the effects of S. chinensis extracts on the melanogenesis signaling pathway activated by alpha-MSH, finding dose-dependent inhibition without provoking cytotoxicity in B16F10 cells. Further, the team found evidence that the depigmenting activity exhibited by S. chinensis extracts may occur as a result of MITF and tyrosinase expression stemming from elevated activity of extracellular signal-regulated kinase (ERK). They concluded that their results support further examination of S. chinensis for its potential to contribute to skin whitening.5
Conclusion
Multiple lignan constituents in this plant-derived ingredient appear to yield anti-inflammatory, antioxidant, photoprotective, and antitumor properties. Its inhibitory effects on melanin production and its antiaging abilities make it worthy of further study and consideration of inclusion in antiaging skin care products.
Dr. Baumann is a private practice dermatologist, researcher, author, and entrepreneur in Miami. She founded the division of cosmetic dermatology at the University of Miami in 1997. The third edition of her bestselling textbook, “Cosmetic Dermatology,” was published in 2022. Dr. Baumann has received funding for advisory boards and/or clinical research trials from Allergan, Galderma, Johnson & Johnson, and Burt’s Bees. She is the CEO of Skin Type Solutions, a SaaS company used to generate skin care routines in the office and as an e-commerce solution. Write to her at [email protected].
References
1. Zhang J et al. J Ethnopharmacol. 2021 Oct 28;279:114400.
2. Yoo HJ et al. J Ethnopharmacol. 2008 Nov 20;120(2):282-6.
3. Kim BW et al. BMC Complement Altern Med. 2014 Dec 16;14:502.
4. Lee DH et al. Biol Pharm Bull. 2013;36(5):772-9.
5. Lee YJ et al. Biol Pharm Bull. 2012;35(8):1361-6.
6. Choi MS et al. Biol Pharm Bull. 2008 Jan;31(1):51-6.
7. Park G et al. Biol Pharm Bull. 2013;36(7):1134-9.
8. Bae HB et al. Int Immunopharmacol. 2010 Sep;10(9):1022-8.
9. Seo CS et al. Phytother Res. 2009 Nov;23(11):1531-6.
10. Lee HD et al. Exp Dermatol. 2011 Sep;20(9):761-3.
11. Yun JY et al. Arch Pharm Res. 2011 Aug;34(8):1339-45.
12. Chang H et al. Pigment Cell Melanoma Res. 2012 Nov;25(6):765-72.
Also known as Asian or Chinese lizard’s tail (or Sam-baekcho in Korea), Saururus chinensis is an East Asian plant used in traditional medicine for various indications including edema, gonorrhea, jaundice, hypertension, leproma, pneumonia, and rheumatoid arthritis.1,2 Specifically, Korean traditional medicine practitioners as well as Native Americans and early colonists in what is now the United States used the botanical to treat cancer, edema, rheumatoid arthritis, and other inflammatory conditions.2-4 Modern research has produced evidence supporting the use of this plant in the dermatologic realm. This column focuses on the relevant bench science and possible applications.
Various beneficial effects
In 2008, Yoo et al. found that the ethanol extract of the dried aerial parts of S. chinensis exhibit anti-inflammatory, antiangiogenic, and antinociceptive properties, which they suggested may partially account for the established therapeutic effects of the plant.2 Also, Lee et al. reported in 2012 on the antiproliferative effects against human cancer cell lines of neolignans found in S. chinensis.5
Antioxidant properties have been associated with S. chinensis. In 2014, Kim et al. reported that S. chinensis extract attenuated the lipopolysaccharide (LPS)-stimulated neuroinflammatory response in BV-2 microglia cells, a result that the authors partly ascribed to the antioxidant constituents (particularly quercetin) of the plant.3
Atopic dermatitis
In 2008, Choi et al. determined that the leaves of S. chinensis impeded the formation of atopic dermatitis–like skin lesions in NC/Nga mice caused by repeated application of picryl chloride, potentially by stimulating the Th1 cell response, thus modulating Th1/Th2 imbalance. They concluded that S. chinensis has potential as an adjunct treatment option for atopic dermatitis.6
Anti-inflammatory activity
In 2010, Bae et al. studied the anti-inflammatory properties of sauchinone, a lignan derived from S. chinensis reputed to exert antioxidant, anti-inflammatory, and hepatoprotective activity,7 using LPS-stimulated RAW264.7 cells. They found that the lignan lowered tumor necrosis factor (TNF)–alpha synthesis by inhibiting the c-Raf-MEK1/2-ERK1/2 phosphorylation pathway, accounting for the anti-inflammatory effects of the S. chinensis constituent.8
More recently, Zhang et al. determined that the ethanol extract of S. chinensis leaves impaired proinflammatory gene expression by blocking the TAK1/AP-1 pathway in LPS-treated RAW264.7 macrophages. They suggested that such suppression is a significant step in the anti-inflammatory function exhibited by the plant.1
Photoprotection
Park et al. investigated in 2013 the beneficial effects of sauchinone. Specifically, they studied potential photoprotective effects of the lignan against UVB in HaCaT human epidermal keratinocytes. They found that sauchinone (5-40 mcm) conferred significant protection as evaluated by cell viability and a toxicity assay. At 20-40 mcm, sauchinone blocked the upregulation of matrix metalloproteinase (MMP)–1 proteins and decrease of type 1 collagen engendered by UVB exposure. The investigators further discovered that sauchinone diminished the synthesis of reactive oxygen species. Overall, they determined that sauchinone imparted protection by suppressing extracellular signal-regulated kinase, c-Jun N-terminal kinase, and p38 MAPK signaling through the activation of oxidative defense enzymes.7
Potential use as a depigmenting agent
In 2009, Seo et al. isolated the lignans manassantin A and B from S. chinensis and determined that these compounds dose-dependently impeded melanin synthesis in alpha-melanocyte stimulating hormone (alpha-MSH)–activated melanoma B16 cells. They also noted that manassantin A suppressed forskolin- or 3-isobutyl-1-methylxanthine (IBMX)–induced melanin production and diminished cellular levels of IBMX-inducible tyrosinase protein. The lignan had no effect on the catalytic activity of cell-free tyrosinase, an important enzyme in melanin pigment production. The researchers concluded that their results suggest the potential for S. chinensis to be used to treat hyperpigmentation disorders.9
Two years later Lee et al. found that manassantin A, derived from S. chinensis, steadily suppressed the cAMP elevator IBMX- or dibutyryl cAMP-induced melanin synthesis in B16 cells or in melan-a melanocytes by down-regulating the expression of tyrosinase or the TRP1 gene. The lignan also inhibited microphthalmia-associated transcription factor (MITF) induction via the IBMX-activated cAMP-responsive element-binding protein (CREB) pathway, thus preventing the Ser-133 phosphorylation of CREB. The researchers concluded that this molecular disruption of melanin production suggests the potential for the use of manassantin A as a skin depigmenting agent.10
That same year, another S. chinensis lignan gained interest. Yun et al. investigated the effects of the S. chinensis lignan component saucerneol D on melanin synthesis in cAMP-elevated melanocytes. They found that the lignan efficiently impeded melanin product in B16 melanoma cells stimulated with alpha-MSH or other cAMP elevators. Saucerneol D was also credited with down-regulating alpha-MSH–induced gene expression of tyrosinase at the transcription level in B16 cells, suppressing alpha-MSH–induced phosphorylation of CREB in the cells, and inhibiting MITF induction. The investigators concluded that their results point to the potential of the S. chinensis lignan saucerneol D for the treatment of hyperpigmentation disorders.11
In 2012, Chang et al. observed that an extract of S. chinensis and one of its constituent lignans, manassantin B, prevented melanosome transport in normal human melanocytes and Melan-a melanocytes, by interrupting the interaction between melanophilin and myosin Va. The investigators concluded that as a substance that can hinder melanosome transport, manassantin B displays potential for use as depigmenting product.12
The following year, Lee et al. studied the effects of S. chinensis extracts on the melanogenesis signaling pathway activated by alpha-MSH, finding dose-dependent inhibition without provoking cytotoxicity in B16F10 cells. Further, the team found evidence that the depigmenting activity exhibited by S. chinensis extracts may occur as a result of MITF and tyrosinase expression stemming from elevated activity of extracellular signal-regulated kinase (ERK). They concluded that their results support further examination of S. chinensis for its potential to contribute to skin whitening.5
Conclusion
Multiple lignan constituents in this plant-derived ingredient appear to yield anti-inflammatory, antioxidant, photoprotective, and antitumor properties. Its inhibitory effects on melanin production and its antiaging abilities make it worthy of further study and consideration of inclusion in antiaging skin care products.
Dr. Baumann is a private practice dermatologist, researcher, author, and entrepreneur in Miami. She founded the division of cosmetic dermatology at the University of Miami in 1997. The third edition of her bestselling textbook, “Cosmetic Dermatology,” was published in 2022. Dr. Baumann has received funding for advisory boards and/or clinical research trials from Allergan, Galderma, Johnson & Johnson, and Burt’s Bees. She is the CEO of Skin Type Solutions, a SaaS company used to generate skin care routines in the office and as an e-commerce solution. Write to her at [email protected].
References
1. Zhang J et al. J Ethnopharmacol. 2021 Oct 28;279:114400.
2. Yoo HJ et al. J Ethnopharmacol. 2008 Nov 20;120(2):282-6.
3. Kim BW et al. BMC Complement Altern Med. 2014 Dec 16;14:502.
4. Lee DH et al. Biol Pharm Bull. 2013;36(5):772-9.
5. Lee YJ et al. Biol Pharm Bull. 2012;35(8):1361-6.
6. Choi MS et al. Biol Pharm Bull. 2008 Jan;31(1):51-6.
7. Park G et al. Biol Pharm Bull. 2013;36(7):1134-9.
8. Bae HB et al. Int Immunopharmacol. 2010 Sep;10(9):1022-8.
9. Seo CS et al. Phytother Res. 2009 Nov;23(11):1531-6.
10. Lee HD et al. Exp Dermatol. 2011 Sep;20(9):761-3.
11. Yun JY et al. Arch Pharm Res. 2011 Aug;34(8):1339-45.
12. Chang H et al. Pigment Cell Melanoma Res. 2012 Nov;25(6):765-72.