Silicone gel sheeting

Silicone gel sheeting (SGS) has been an effective reduction and preventive scar therapy since 1980.[1] It was first discovered to be used in treating scars by Perkins in Australia and New Zealand, and first discussed in the thesis of Karen Quinn, a British biomedical engineering student, in 1985.[2]

Silicone gel sheet (beige)

It is now considered the first-line prevention and treatment for hypertrophic and keloid scars by occlusion and then hydration of the scar tissue.[3] Silicone gel is made of medical-grade silicone polymers.[4] Silicone gel sheet consists of a soft, semi-occlusive sheet and a membrane that increases the durability of the sheet.[3] The sheet has a solid rubber-like appearance.

Although the mechanism of action of silicone gel sheeting remains partially unknown, its efficacy is confirmed by many clinical trials,[5] and is similar to silicone gel.[6]

Medical use

Hypertrophic scar

Silicone gel sheeting is the gold-standard and non-invasive treatment for hypertrophic and keloid scars. During skin injury repair, dermal cells proliferate and migrate from the skin tissue to the wound, producing collagen and causing contraction of the placement dermis.[5] These scars are proliferative due to chronic inflammation and overproduction of abnormal collagen.[7] Common clinical presentations of these scars are raised, thickened, red, or dark-colored.[4] Patients may also experience pain and itching.[8]

Hypertrophic scars are elevated scars that remain in the region of the original lesion[9] following mechanical traumas, burns, and necrotizing infections.[10] These scars typically develop in locations under tension, such as shoulders, ankles, knees, and the neck.[8] Hypertrophic scars are generally confined to the boundaries of the original wound and tend to diminish over time.[11]

Keloids

Keloids grow extensively beyond the wound margins and tend to persist or even worsen over time.[11] They are relatively difficult to treat due to their high risk of recurrence.[9] Keloids are more common in people with darker skin tones[12] and often occur in individuals with a genetic predisposition.[13] Keloids are the most extreme type of scarring since minor wounds such as insect bites or piercings can all lead to an elevated tissue area. Patients may experience psychological trauma if their scars are not well-controlled.[8] Therefore, the prevention of wound formation is crucial to them. They should avoid undergoing any unnecessary invasive procedures or cosmetic surgeries.[14]

The beneficial effects of silicone gel sheeting on the treatment and prevention of these two scars have been confirmed.[10] Since most patients develop hypertrophic and keloid scars within 3 months after surgery or injury, the silicone gel sheeting therapy should be started in the early repair phase to achieve an optimal therapeutic effect. The maturity of scars takes over a year; therefore, silicone treatment is also effective in scars aged over 12 months.[15] The therapy usually requires 6 to 12 months of constant wear to achieve optimum results. Recent data suggest that the combination of silicone gel sheeting and pressure therapy can improve post-traumatic scar healing.[4]

Use

The sheet should not be used on open wounds.[16][17] The sheet is reusable with proper cleaning though it should be replaced when it starts to deteriorate.[16]

Mechanism of action

The exact mechanism of action of silicone gel sheeting has not been fully studied. Currently, many proposed mechanisms explain the efficacy of such treatment, including the occlusion and hydration effect, increased body surface temperature, polarized electric charge, immunological effects, etc.[9] The occlusion and hydration effect is the most studied mechanism of action. 

Occlusion and Hydration

Silicone gel sheets occlude and hydrate the stratum corneum of the treated skin area. The stratum corneum normally conserves water and acts as a barrier to microbial infection. Its function can be disrupted by wound formation. The stratum corneum of hypertrophic scars and keloids absorbs more water than normal skin, depleting the water supply from the stratum corneum. Excessive dehydration of keratinocytes stimulates cytokine production, leading to increased collagen production.[18][5] After applying the sheet, the rate of water loss via evaporation of the treated skin area is half of the untreated area. Therefore, the sheet prevents the drying up of stratum corneum, and thus further collagen production. Collagen production exacerbates the growth of hypertrophic scars and keloids and thus should be avoided.[9][5] Hydrating a scar over a prolonged period can also relieve symptoms such as itching and pain. Such an effect is likely due to decreased capillary activity and thus local collagen deposition.[9]

Temperature

Applying silicone gel sheeting causes a slight increase in surface temperature. Increased temperature intensifies the activity of collagenase, an enzyme that breaks down collagen. Since excessive collagen production leads to scar formation, increased levels of collagenase may help reduce the risk of scar formation.[9]

Epidermal-dermal signaling

Silicone-related products can reduce the growth factor production of fibroblasts in hypertrophic scars and keloids.[19] However, the relevance is unclear as silicone products do not have direct contact with dermal fibroblasts but with the epidermis only. Possible relevance may be due to the initiation of a signaling cascade by the epidermis. Through the signaling cascade, the epidermis regulates dermal fibroblast extracellular matrix production. Delayed epithelialization, which raises the risk of hypertrophic scar formation, is less likely to happen.[18]

A negative static electric charge is formed by friction between the silicone gel sheet and the skin. The charge induces collagen realignment, aiding the elimination of the scar.[18] Moreover, the negative electric field leads to the polarization of scar tissues and thus scar shrinkage.[9]

Effectiveness

Silicone gel sheeting has remained the first-line therapy stated by international clinical recommendations on scar management.[5]

Scar measurements studied in most clinical trials include color (vascularisation and pigmentation), thickness (height: clinical and histological), relief (surface irregularities), pliability (tissue elasticity), and surface area (scar contraction or expansion).[20]

Scar elevation index is commonly used to indicate scar improvement. It measures the height of scar tissue compared to the normal surrounding skin.[21] Studies show the effectiveness of silicone gel sheeting in minimizing scar elevation index.[22] Another physical measure is the pliability of the scar tissue, which is also improved by silicone gel sheeting.[23] Scar improvement is generally measured by size reduction, appearance, and calming effect. Silicone gel sheeting addresses the 3 requirements well among scar treatments.[5] Several randomized controlled trials were carried out to assess the effectiveness. Silicone gel sheeting produces a statistically significant reduction in scar thickness and color amelioration. Therefore, it is an evidence-based non-invasive preventive treatment.[24]

Results of comparative studies on the effectiveness of silicone gel sheeting and silicone gel do not show significant differences between the two.[25]

Another non-invasive treatment is compression therapy, in which patients wear pressure garments to control the growth of scars. Pressure garments apply mechanical pressure to the surface of the scar, reducing the supply of blood and oxygen to the scar tissue. Formation of excessive scar tissue is thus prevented. The combination of silicone gel sheeting and compression therapy has been proven to be more effective than using the sheet alone.[26]

Patients who find the non-invasive treatments ineffective may choose to undergo invasive treatments such as intralesional injections of corticosteroids, surgical excision of the scars, and radiotherapy.[26][27]

Side effects

Common side effects of silicone gel sheets include itchiness, rash, maceration of the skin, and malodor.[28] These symptoms are generally well-tolerated and can be minimized by rinsing the area properly daily. Patients who suffer from these side effects should wash the treated area and the silicone gel sheets with mild soap since the dirt or bacteria on the sheets may irritate the scar.[16] In tropical climates with high humidity, excessive moisture underneath the gel may lead to heat rash and uncomfortable sensations in patients.[2]

Design

Silicone gel sheets are usually made of medical silicone polymers such as polysiloxane and polydimethylsiloxane, along with silicon dioxide and volatile components. The long-chain silicone polymers form cross-linking with silicon dioxide and spread as a thin sheet.[8]

They are either flesh color (most common) or clear and come as either a single large rectangle sheet or a roll. Available size varies with brands.

Notable brands

[29]

  • Advasil Conform: Polyurethane film backing and self-adhesive
  • Bapscarcare T: Self-adhesive
  • Cica-care: Soft, self-adhesive, and semi-occlusive with backing
  • Ciltech: Polyurethane film backing and self-adhesive
  • Dermatix: Self-adhesive (transparent or fabric-backed)
  • Mepiform: Polyurethane film backing and self-adhesive
  • Scar FX: Self-adhesive and transparent
  • Silgel: Thin and transparent

References

  1. Wang, Fan; Li, Xiaoxue; Wang, Xiuyun; Jiang, Xian (June 2020). "Efficacy of topical silicone gel in scar management: A systematic review and meta‐analysis of randomised controlled trials". International Wound Journal. 17 (3): 765–773. doi:10.1111/iwj.13337. ISSN 1742-4801. PMC 7949016. PMID 32119763.
  2. Mustoe, Thomas A. (2020), Téot, Luc; Mustoe, Thomas A.; Middelkoop, Esther; Gauglitz, Gerd G. (eds.), "Silicone Gel for Scar Prevention", Textbook on Scar Management: State of the Art Management and Emerging Technologies, Cham: Springer International Publishing, pp. 203–208, doi:10.1007/978-3-030-44766-3_23, ISBN 978-3-030-44766-3, PMID 36351129, S2CID 235058739, retrieved 2023-03-13
  3. Monstrey, Stan; Middelkoop, Esther; Vranckx, Jan Jeroen; Bassetto, Franco; Ziegler, Ulrich E.; Meaume, Sylvie; Téot, Luc (2014-08-01). "Updated Scar Management Practical Guidelines: Non-invasive and invasive measures". Journal of Plastic, Reconstructive & Aesthetic Surgery. 67 (8): 1017–1025. doi:10.1016/j.bjps.2014.04.011. ISSN 1748-6815. PMID 24888226.
  4. Ottenbrite, R. M.; Javan, R. (2005-01-01), "Biological Structures", in Bassani, Franco; Liedl, Gerald L.; Wyder, Peter (eds.), Encyclopedia of Condensed Matter Physics, Oxford: Elsevier, pp. 99–108, ISBN 978-0-12-369401-0, retrieved 2023-03-13
  5. Bleasdale, Benjamin; Finnegan, Simon; Murray, Kathyryn; Kelly, Sean; Percival, Steven L. (2015-07-01). "The Use of Silicone Adhesives for Scar Reduction". Advances in Wound Care. 4 (7): 422–430. doi:10.1089/wound.2015.0625. ISSN 2162-1918. PMC 4486716. PMID 26155385.
  6. O'Brien, Lisa; Jones, Daniel J. (2013-09-12). "Silicone gel sheeting for preventing and treating hypertrophic and keloid scars". The Cochrane Database of Systematic Reviews. 2013 (9): CD003826. doi:10.1002/14651858.CD003826.pub3. ISSN 1469-493X. PMC 7156908. PMID 24030657.
  7. "UpToDate". www.uptodate.com. Retrieved 2023-03-13.
  8. Puri, Neerja; Talwar, Ashutosh (July 2009). "The efficacy of silicone gel for the treatment of hypertrophic scars and keloids". Journal of Cutaneous and Aesthetic Surgery. 2 (2): 104–106. doi:10.4103/0974-2077.58527. ISSN 0974-5157. PMC 2918339. PMID 20808600.
  9. Berman, Brian; Perez, Oliver A.; Konda, Sailesh; Kohut, Bruce E.; Viera, Martha H.; Delgado, Suzette; Zell, Deborah; Li, Qing (November 2007). "A Review of the Biologic Effects, Clinical Efficacy, and Safety of Silicone Elastomer Sheeting for Hypertrophic and Keloid Scar Treatment and Management". Dermatologic Surgery. 33 (11): 1291–1303. doi:10.1097/00042728-200711000-00001. ISSN 1076-0512. PMID 17958580.
  10. Monstrey, Stan; Middelkoop, Esther; Vranckx, Jan Jeroen; Bassetto, Franco; Ziegler, Ulrich E.; Meaume, Sylvie; Téot, Luc (2014-08-01). "Updated Scar Management Practical Guidelines: Non-invasive and invasive measures". Journal of Plastic, Reconstructive & Aesthetic Surgery. 67 (8): 1017–1025. doi:10.1016/j.bjps.2014.04.011. ISSN 1748-6815. PMID 24888226.
  11. Ogawa, Rei (2017-03-10). "Keloid and Hypertrophic Scars Are the Result of Chronic Inflammation in the Reticular Dermis". International Journal of Molecular Sciences. 18 (3): 606. doi:10.3390/ijms18030606. ISSN 1422-0067. PMC 5372622. PMID 28287424.
  12. Gauglitz, Gerd G.; Korting, Hans C.; Pavicic, Tatiana; Ruzicka, Thomas; Jeschke, Marc G. (2011). "Hypertrophic scarring and keloids: pathomechanisms and current and emerging treatment strategies". Molecular Medicine. 17 (1–2): 113–125. doi:10.2119/molmed.2009.00153. ISSN 1528-3658. PMC 3022978. PMID 20927486.
  13. Limandjaja, Grace C.; Niessen, Frank B.; Scheper, Rik J.; Gibbs, Susan (2020). "The Keloid Disorder: Heterogeneity, Histopathology, Mechanisms and Models". Frontiers in Cell and Developmental Biology. 8: 360. doi:10.3389/fcell.2020.00360. PMC 7264387. PMID 32528951.
  14. Berman, Brian; Maderal, Andrea; Raphael, Brian (January 2017). "Keloids and Hypertrophic Scars: Pathophysiology, Classification, and Treatment". Dermatologic Surgery. 43 (1): S3–S18. doi:10.1097/DSS.0000000000000819. ISSN 1076-0512. PMID 27347634. S2CID 21372295.
  15. Wiseman, Jodie; Ware, Robert S; Simons, Megan; McPhail, Steven; Kimble, Roy; Dotta, Anne; Tyack, Zephanie (2019-09-30). "Effectiveness of topical silicone gel and pressure garment therapy for burn scar prevention and management in children: a randomized controlled trial". Clinical Rehabilitation. 34 (1): 120–131. doi:10.1177/0269215519877516. ISSN 0269-2155. PMC 6943962. PMID 31565952.
  16. "Silicone gel sheets — Chelsea and Westminster Hospital NHS Foundation Trust". www.chelwest.nhs.uk. Retrieved 2023-03-13.
  17. "Elaimei Silicone Gel Roll Sheet Scar Medical Removal Patch Tape Wound Skin Repair Treatment Remover Home Keloid Surgery 1.5M". Catch.com.au. Retrieved 2023-03-13.
  18. Mustoe, Thomas A. (January 2008). "Evolution of silicone therapy and mechanism of action in scar management". Aesthetic Plastic Surgery. 32 (1): 82–92. doi:10.1007/s00266-007-9030-9. ISSN 0364-216X. PMID 17968615. S2CID 224394.
  19. Gauglitz, Gerd G.; Korting, Hans C.; Pavicic, Tatiana; Ruzicka, Thomas; Jeschke, Marc G. (January 2011). "Hypertrophic Scarring and Keloids: Pathomechanisms and Current and Emerging Treatment Strategies". Molecular Medicine. 17 (1): 113–125. doi:10.2119/molmed.2009.00153. ISSN 1528-3658. PMC 3022978. PMID 20927486.
  20. Choo, Amanda Min Hui; Ong, Yee Siang; Issa, Fadi (2021). "Scar Assessment Tools: How Do They Compare?". Frontiers in Surgery. 8: 643098. doi:10.3389/fsurg.2021.643098. ISSN 2296-875X. PMC 8260845. PMID 34250003.
  21. Sato, Masato; Ishihara, Miya; Kikuchi, Makoto; Mochida, Joji (November 2011). "The influence of Ho: YAG laser irradiation on intervertebral disc cells". Lasers in Surgery and Medicine. 43 (9): 921–926. doi:10.1002/lsm.21120. PMID 22006735. S2CID 21049261.
  22. Ogawa, Rei; Akaishi, Satoshi; Kuribayashi, Shigehiko; Miyashita, Tsuguhiro (2016). "Keloids and Hypertrophic Scars Can Now Be Cured Completely: Recent Progress in Our Understanding of the Pathogenesis of Keloids and Hypertrophic Scars and the Most Promising Current Therapeutic Strategy". Journal of Nippon Medical School. 83 (2): 46–53. doi:10.1272/jnms.83.46. ISSN 1345-4676. PMID 27180789.
  23. Lane, Joshua E.; Kent, David E. (2007-09-10). "Repair of Vermilion Mohs Defect with Unilateral Axial Myocutaneous Advancement Flap". Dermatologic Surgery. 33 (12): 071009211231010––. doi:10.1111/j.1524-4725.2007.33324.x. ISSN 1076-0512. PMID 18076619.
  24. Monstrey, Stan; Middelkoop, Esther; Vranckx, Jan Jeroen; Bassetto, Franco; Ziegler, Ulrich E.; Meaume, Sylvie; Téot, Luc (August 2014). "Updated Scar Management Practical Guidelines: Non-invasive and invasive measures". Journal of Plastic, Reconstructive & Aesthetic Surgery. 67 (8): 1017–1025. doi:10.1016/j.bjps.2014.04.011. PMID 24888226.
  25. Pruksapong, Chatchai; Burusapat, Chairat; Hongkarnjanakul, Natthawoot (October 2020). "Efficacy of Silicone Gel versus Silicone Gel Sheet in Hypertrophic Scar Prevention of Deep Hand Burn Patients with Skin Graft: A Prospective Randomized Controlled Trial and Systematic Review". Plastic and Reconstructive Surgery. Global Open. 8 (10): e3190. doi:10.1097/GOX.0000000000003190. ISSN 2169-7574. PMC 7647509. PMID 33173695.
  26. Kafka, Mona; Collins, Vanessa; Kamolz, Lars-Peter; Rappl, Thomas; Branski, Ludwik K.; Wurzer, Paul (January 2017). "Evidence of invasive and noninvasive treatment modalities for hypertrophic scars: A systematic review: Evidence of treatment modalities for hypertrophic scars". Wound Repair and Regeneration. 25 (1): 139–144. doi:10.1111/wrr.12507. PMID 28056485. S2CID 3766077.
  27. Kim, Sang Wha (March 2021). "Management of keloid scars: noninvasive and invasive treatments". Archives of Plastic Surgery. 48 (2): 149–157. doi:10.5999/aps.2020.01914. ISSN 2234-6163. PMC 8007468. PMID 33765731.
  28. Medhi, Bikash; Sewal, Rakesh Kumar; Kaman, Lileswar; Kadhe, Ganesh; Mane, Amey (2013-12-01). "Efficacy and Safety of an Advanced Formula Silicone Gel for Prevention of Post-Operative Scars". Dermatology and Therapy. 3 (2): 157–167. doi:10.1007/s13555-013-0036-8. ISSN 2190-9172. PMC 3889307. PMID 24254957.
  29. "[BNF]". MedicinesComplete. 23 April 2019. Retrieved 2023-04-12.
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