Emollient-Based Therapy for AD: A Potential Role for Rebalancing the Microbiome
As the prevalence of atopic dermatitis (AD) increases, especially in developed countries and Western societies,1 affected individuals and those who treat them are interested in innovative approaches to symptom management.
Dysbiosis of the skin microbiota has implications for many of the skin disorders encountered in the clinic, including AD. Mounting evidence suggests the importance of a diverse microbiome for maintaining skin homeostasis, influencing metabolic processes, contributing to immunity, and an overall beneficial effect on skin health.2 It is debatable whether dysbiosis precedes or is a consequence of all skin disorders, though there is evidence that decreased diversity is apparent prior to atopic flares.3 However, overall, the evidence available suggests that rebalancing strategies may be broadly beneficial.
The potential to modulate the skin microbiome via topical product application suggests a tantalizingly simple approach to supporting skin health in individuals with skin symptoms associated with AD, including dryness, xerosis, and itch. Given the chronic nature of the condition, cost-efficient interventions are particularly attractive. And topical modulation of the cutaneous microbiota represents an attractive approach to patient care.
La Roche-Posay has been actively researching and conducting clinical studies to better understand the skin microbiome for 10 years. The company continues to fund research in efforts to enhance clinical knowledge and produce solutions that could have important benefits to support symptom management.
Rethinking Emollients
Topical emollient products, either nonpharmacologic or prescription, are used as monotherapy or as adjuncts to other courses of therapy in AD to soften and moisturize the skin and possibly to help restore stratum corneum deficits that lead to disruption of barrier function. However, clinicians recognize that the quality and clinical effect of emollient formulations can vary significantly. In fact, some ingredients have been suggested to degrade the skin barrier, while others have been shown to offer barrier support. Recently, the potential to support a healthy skin microbiome via topical formulations has gained increased attention.
La Roche-Posay has pioneered research into topical modulation of the skin microbiome, with the goal to deliver rigorously proven, clinically beneficial products to help manage the symptoms of AD and reduce flares. Since 1905, thermal dermatology patients have visited the center in the town of La Roche-Posay, France for management of eczema and other skin disorders. Insurers in France currently cover these treatments for patients with AD, psoriasis, and related skin diseases. The history of successful skin improvement associated with bathing in the springs inspired the company La Roche-Posay to formulate at-home solutions for skin care, incorporating La Roche-Posay Thermal Spring water (LRP-TSW). The company has been dogged in its mission to understand how LRP-TSW confers benefits and to deliver that benefit in commercially available skincare.4
LRP-TSW has a specific and unique mineral and bacterial fingerprint that is only found in the water from this particular spring.4 Its unique composition can be associated with a proprietary ingredient called Aqua Posae Filiformis (APF), a biomass consisting of prebiotics, as well as postbiotic products. APF is a lysate of Vitreoscilla Filiformis grown in LRP-TSW containing medium with demonstrated benefits on inflammation and immunoregulation. Evidence suggests that LRP-TSW and APF formulations may have skin supportive benefits that help to rebalance the microbiome.
To date, LRP-TSW and APF-containing products have been tested in multiple clinical studies by LRP, which has the data on file, and which have been published in peer reviewed dermatology journals. These trials have been a blend of clinical and observational studies, with study endpoints dependent on an investigator evaluation and outcomes from patient self-reporting. Data are also available from studies evaluating LRP-TSW and APF-containing products used alone or in conjunction with what may be considered standard of care for AD, such as topical corticosteroids.
Study Data
Real-world Benefit. Evidence supports the benefits of using LRP-TSW and APF-containing products—alone or with conventional therapeutics—to improve AD symptoms. Data from an international observational trial performed in 11 countries and involving 9,035 patients aged four days to 91 years with mild to moderate AD (five percent of patients had severe AD) provides a glimpse of how an emollient formulation containing LRP-TSW and APF might perform in a real world setting. Investigator-rated improvements in clinical outcomes were similar when the formulation was used as a stand-alone intervention or when used along with standard therapeutic interventions for AD. Similarly, patient-reported improvements in quality of life metrics were similar whether the formulation was used as monotherapy or in combination therapy (Figures 1 and 2).
Figure 1. QOL + Evaluation of Eczema Improvement and Tolerability - Monotherapy
Figure 2. QOL + Evaluation of Eczema Improvement and Tolerability - Adjunctive therapy
Reduction of prescription use. Another study—this time in 2,568 children aged one month to 18 years—suggests that use of the LRP-TSW and APF-containing emollient may allow for a reduction in use of corticosteroids and other treatments. A majority (83.4 percent) of 1,353 patients using a steroid were able to reduce the frequency steroid use, and 71.5 percent of 907 users reduced antihistamine use (a boon given the use of antihistamines in AD is against current recommendations), once they added the emollient to their regimen.
Symptom improvement and flare reduction. LRP-TSW plus APF-containing products may not only rapidly improve AD symptoms but also help reduce AD flares. A double blind study performed on two groups of 50 AD patients showed that one month after the end of an efficient therapeutic treatment, 84 percent of patients using an LRP-TSW and APF based emollient were in maintenance versus 61 percent for a comparator emollient. Furthermore, in case of relapse, the global worsening of SCORAD rates were 16 percent and 39 percent, respectively, with significantly less product use (192g versus 224g). As well, skin samples taken from subjects in each group demonstrated greater Stahylococcus reduction in the Lipikar group compared to the reference emollient in both affected and unaffected skin areas.18 While these are small numbers of patients studied, they nevertheless suggest a benefit for strategies centered on rebalancing the skin microbiome to achieve more physiologic conditions.
Outcomes indicative of good compliance are important to note: 85 percent reported that LRP-TSW-based emollient moisturized all day long, 94 percent said it was easily spreadable, and 96 percent reported that the application was easy to use. As well, 89 percent had a reduced desire to scratch.
A separate evaluation that looked at tolerance and SCORAD reduction in 51 children and adults with moderate to severe AD showed that the LRP-TSW-based emollient notably reduced pruritus by day 14 (average 41 percent reduction) and was associated with improvement in sleep for 86 percent of subjects by day 14.
Rebalancing the Skin Microbiome: A Plausible AD Treatment Strategy
The efficacy demonstrated by the LRP-TSW and APF-based emollient in accumulated studies may be explained in part by several unique biological impacts. Clinical studies have shown that topical LRP-TSW treatment has a prebiotic demonstrated activity, resulting in increases in Gram-negative bacteria and improvment in skin microbial diversity.4 In addition, in vitro testing on reconstructed epidermis, with APF demonstrated that it stimulated endogenous antioxidant and antimicrobial defenses.19
Secondly, it may also contribute to rebalancing of the skin’s microbiome by supporting growth of beneficial commensal bacteria. There is evidence that treatment with LRP-TSW and/or APF may encourage propagation of the Xanthomonas genus of the Protobacteria phylum, which paralleled clinically longer durations between AD flares and less severe ones.20 Interestingly, studies showed that as Xanthomonas population increased, Staphylococcus communities decreased.21
Conclusion
The growing body of research on the role of dysbiosis in skin disease underscores the importance of choosing the proper topical emollient to manipulate the cutaneous microbiota for a given patient. No longer is the goal of topical emollients simply to soften the skin feel or prevent moisture loss. Rather, the prospect of rebalancing the skin microbiome through topical product application offers intriguing potential for the management of AD. Efforts to restore bacterial loads and diversity in affected skin areas appears to equip the human body (and perhaps the immune system) with a better chance of restoring damage and maintaining skin health.
1. Shaw TE, Currie GP, Koudelka CW, Simpson EL. Eczema prevalence in the United States: data from the 2003 National Survey of Chil-dren’s Health. J Invest Dermatol 2011;131:67–73.
2. Grice EA. The skin microbiome: potential for novel diagnostic and therapeutic approaches to cutaneous disease. Semin Cutan Med Surg. 2014 June; 33(2):98-103.
3. Kong HH, Oh J, Deming C, et al.Temporal shifts in the skin microbiome associated with disease flares and treatment in children with atopic dermatitis. Genome Res. 2012 May;22(5):850-9.
4. 4. Zeichner J, Seite S. From Probiotic to Prebiotic Using Thermal Spring Water. J Drugs Dermatol. 2018 Jun 1;17(6):657-662.
5. Weidinger S, Novak N. Atopic dermatitis. Lancet. 2016;387:1109-22.
6. Garmhausen D, Hagemann T, Bieber T, et al. Characterization of different courses of atopic der-matitis in adolescent and adult patients. Allergy. 2013;68:498–506.
7. Illi S, von Mutius E, Lau S, et al. The natural course of atopic dermatitis from birth to age 7 years and the association with asthma. J Allergy Clin Immu-nol. 2004;113:925–31.
8. Margolis JS, Abuabara K, Bilker W, Hoffstad O, Margolis DJ. Persistence of mild to moderate atopic dermatitis. JAMA Dermatol. 2014;150:593–600.
9. Napolitano M, Megna M, Patruno C, et al. Adult atopic dermatitis: a review. G Ital Dermatol Vener-eol. 2016;151:403–11.
10. Silverberg JI, Gelfand JM, Margolis DJ, et al. Atopic Dermatitis in US Adults: From Population to Health Care Utilization. J Allergy Clin Immunol Pract. 2019 May-Jun;7(5):1524-1532.
11. Silverberg JI, Hanifin JM. Adult eczema prevalence and associations with asthma and other health and demographic factors: a US population-based study. J Allergy Clin Immunol. 2013;132:1132–8.
12. Neish AS. Microbes in Gastrointestinal Health and Disease. Gastroenterology. 2009 Jan; 136(1): 65–80.
13. NIH HMP Working Group. Genome Res. 2009;19:2317-2323.
14. Grice EA, Kong HK, Conlan S, et al. Topographical and temporal diversity of the human skin microbiome. Science. 2009; 324(5931):1190–1192.
15. Costello EK, Lauber CL, Hamady M, Fierer N, Gordon JI, Knight R. Bacterial community variation in human body habitats across space and time. Science. 2009; 326(5960):1694–1697. [PubMed: 19892944]
16. Huang JT, Abrams M, Tlougan B, Rademaker A, Paller AS. Treatment of Staphylococcus aureus colonization in atopic dermatitis decreases disease severity. Pediatrics. 2009; 123(5):e808-814.
17. Kong HH, Oh J, Deming C, et al. Temporal shifts in the skin microbiome associated with disease flares and treatment in children with atopic dermatitis. Genome Res. 2012; 22(5):850-859.
18. Seité S, Zelenkova H, Martin R. Clinical efficacy of emollients in atopic dermatitis patients - relationship with the skin microbiota modification. Clin Cosmet Investig Dermatol. 2017 Jan 12;10:25-33.
19. Mahe YF, Perez MJ, Tacheau C, Fanchon C, Martin R, Rousset F, Seite S. A new Vitreoscilla filiformis extract grown on spa water-enriched medium activates endogenous cutaneous antioxidant and antimicrobial defenses through a potential Toll-like receptor 2/protein kinase C, zeta transduction pathway. Clin Cosmet Investig Dermatol. 2013 Aug 30;6:191-6.
20. Seite S, Flores GE, Henley JB, Martin R, Zelenkova H, Aguilar L, Fierer N. Microbiome of affected and unaffected skin of patients with atopic dermatitis before and after emollient treatment. J Drugs Dermatol. 2014 Nov;13(11):1365-72.
21. Yamamura S, et al. Keratin degradation: a cooperative action of two enzymes from Stenotrophomonas sp. Biochem Biophys ResCommun. 2002 Jun 28;294(5):1138-43.
Ready to Claim Your Credits?
You have attempts to pass this post-test. Take your time and review carefully before submitting.
Good luck!
Recommended
Linda Stein Gold, MD
Jashin J. Wu, MD, FAAD
- Digital Supplement
Bimekizumab-bkzx Journal Scan: 4 Clinical Trials
Jason Hawkes, MD
- Supplements
Preparing for the Future of Teledermatology