Table 1: Common topical steroids used in keloid management.

Topical Steroids: Efficacy, Successes and Improvements

Scar types and formulations are two main factors that predict the efficacy of topical steroid creams. The reported success of topical steroid creams has shown to relieve symptoms and improve scar characteristics with their consistent application. Topical corticosteroid therapy provides symptomatic relief from pruritus (itching) and pain. TA lotion combined with an occlusive film was used in a study and has reported that 6 out of 9 keloid patients who complained of itchiness experienced improvement after starting treatment [25]. In terms of scar height, one trial assessed the use of methylprednisolone cream for post-Cesarean scars after the three-month evaluation; the scar was significantly reduced compared to the control group [28]. In addition to the scar height, the overall appearance was improved after the use of topical TA lotion in 44% of keloid patients in at least three parameters out of five and they are colour, itchiness, elevation, texture and pain [25]. Furthermore, patient satisfaction was a positive factor for the potential use of topical steroids in keloids. One study compared methylprednisolone cream and silicone gel after a Pfannenstiel incision. Patients were satisfied with methylprednisolone group (48%) than in the silicone group (33%) or the control group (11%) and scored higher out of all groups (Table 2) [29]. Fig. 1 demonstrates the effectiveness of topical steroids on keloid scars.

Table 2: Outcomes of tropical steroid studies.

Figure 1: The efficacy of topical steroids in improving keloid scar.

The following figure shows the application of topical steroids on keloid scars by decreasing the overproduction of collagen and altering the underlying mechanism. The results improve the overall appearance of the scar.

Why Topical Steroids Aren’t Always Effective (Limitations)

The common limitation of applying topical steroid monotherapy is due to various reasons, such as the maturity of the scar and dense keloids. One of the drawbacks of using topical steroids is the temporary effects after the treatment is discontinued. A prophylactic study of methylprednisolone cream for post-Cesarean scars, while positive effects were seen for vascularity and height at three months, the outcomes were similar to the control group at six months [28]. Poor absorption and penetration are common limitations that result in low transdermal efficiency, reduction of drug concentration and a short duration of action [28]. Lastly, a lack of large-scale randomized controlled studies can lead to practice reluctance [30].

Adverse Effects

The extended use of topical steroids is a critical consideration for scar management due to their adverse effects. Skin atrophy after long-term use of topical steroids is commonly associated with intralesional corticosteroid injections [31]. Telangiectasias are the formation of spider veins, which is a potential local side effect of prolonged topical corticosteroid use [21]. Hypopigmentation or general pigment changes are concerns associated with steroid use, particularly in patients with Fitzpatrick skin types IV-VI (skin of colour) [32]. Systemic complications, such as Cushing’s syndrome, occur with high doses or prolonged application over large surface areas [33]. Other reported side effects include contact dermatitis, local irritation, itching, skin maceration and folliculitis [26].

Combination Therapies

Topical steroid creams and ointments are frequently used as part of multimodal treatment protocols to enhance efficacy and reduce recurrence rates. Fig. 2. Exemplifies the diverse combination therapies of topical steroids in keloid treatment.

1. Combination with Surgical Excision and Injections: The combination of five intralesional Triamcinolone Acetonide (TA) injections every 2 weeks after suture removal, with self-administered topical steroid ointment daily for 6 months, was used to reinforce the effect of injected steroids. This approach resulted in a low rate of keloid for 14.3% [27]. Similarly, the combination treatment of surgical excision and subsequent intralesional TA injection with a recurrence rate of less than 50% [34]
2. Combination with Occlusive Dressings (Silicone/Pressure Garments): To increase percutaneous absorption, incorporating topical steroids and occlusion. One trial compared Clobetasol Propionate 0.05% cream under silicone dressing occlusion versus intralesional TA for keloid treatment [22]. Silicone gel sheeting can serve as an adjunct to other therapies due to its low adverse effect profile and ability to modulate scar formation [35]. TA lotion combined with cynthaskin can form an adherent and transparent occlusive film used for exposed parts of the body with scars [25]. Another therapy used after surgery is using triple therapy by using TA cream and intrakeloidal injections with long pressure applications of silicone gel strip/sheets. The success of this regimen was recorded at a rate of 87.5% at 13 months, although it was noted to be time-consuming and tedious [36]
3. Combination with Laser-Assisted Drug Delivery (LADD): Combining LADD and topical steroids can facilitate topical drugs to have deeper penetration [37]. A study has shown that the use of topical TA with CO2 laser can decrease scar volume in comparison to intralesional TA injections [37]. Another study was conducted by combining topical betamethasone cream to treat keloids that are resistant to first-line therapies and with an improvement of 50% and reported a reduction of pruritus and pain [38]. The LADD approach is considered a safer and better aesthetic treatment option than standard injections (Table 3)

Figure 2: Topical steroid combination therapies in keloid management flow-chart.

Table 3: Summary of keloid treatment options.

Discussion

The Difference Between Keloid and Hypertrophic Scars

Both keloids and Hypertrophic Scars (HTS) have similarities, whether from their abnormal responses to wound healing to their common causes, such as cutaneous injury or irritation from trauma, tattoos, piercings, surgery, burns, insect bites, acne, abscess or vaccination. Crucially, superficial injuries that do not reach the reticular dermis do not cause keloidal or hypertrophic scarring. At the beginning of the injury, HTS and keloids are similar in scarring, but with healing, differentiation begins to occur, which is why misdiagnosis between HTC and keloids.

Differentiation

The primary clinical distinction between keloids and HTS is growth pattern. Keloid scars tend to extend from their original boundaries in their direction of healing, with a distortion of the lesion and a pseudo-tumoral nature by invading the surrounding healthy skin. Whereas HTS remain within the boundaries of the original wound and yet regress over months and years spontaneously after the initial injury [39].

Another difference is the pathology between HTN and keloids; keloids are characterized by the presence of thick, haphazardly arranged collagen fibers called keloidal or hyalinized collagen bundles, which are fewer in HTS. HTS collagen bundles are typically smaller, flatter, less demarcated and arranged in a wavy or parallel pattern. However, many lesions exhibit intermediate characteristics, making clinical differentiation challenging. Some experts propose that keloids and HTS are fundamentally the same fibroproliferative skin disorder and differ only in the intensity, frequency and duration of the chronic inflammation of the reticular dermis.  HTS are typically limited in their wound margins, respond normally to growth hormones and may contain mainly Type III collagen arranged parallel to the epidermal surface (Table 4) [40].

Table 4: Clinical and histopathological differences between keloids and hypertrophic scars.

Future Directions of Steroid Applications in Keloids

The future of keloid therapeutic management is progressively evolving from empirical treatments toward targeted molecular therapies and advanced biological agents [30]. A deeper understanding of the molecular pathways responsible for pathological scarring has identified Transforming Growth Factor-beta (TGF-β) as a primary target, with future treatments potentially utilising recombinant TGF-β3, interleukin-10 and imatinib mesylate to inhibit fibrogenic signalling [6]. Innovative research is exploring the use of RNA interference (RNAi) and microRNA-based therapies, such as VEGF siRNA, to suppress angiogenesis and silence specific transcription factors like Runx2 that drive excessive collagen deposition [41]. Furthermore, mechanistic checkpoints observed in tumor growth, for example, fibroblast activation protein alpha (FAP-α) and CTHRC1, are being investigated as novel targets to halt the aggressive, invasive nature of keloid tissue [5]. Technological advancements in drug delivery systems are also central to upcoming management strategies, shifting toward non-invasive transdermal methods to replace painful injections. These include dissolving microneedle patches, nanocarrier systems like transfersomes and Laser-Assisted Drug Delivery (LADD), which creates microscopic channels to ensure a uniform distribution of medications throughout the dense scar matrix [21]. Additionally, cell-based therapies involving Mesenchymal Stem Cells (MSCs), Adipose-Derived Stem Cells (ADSCs) and autologous fat grafting are undergoing large-scale trials to determine their efficacy in modulating chronic inflammation and improving tissue pliability [41].

Conclusion

The treatment of pathological keloid scars remains fundamentally challenged due to the lack of standardized therapy and the limited understanding of the primary underlying mechanism. This lack of understanding necessitates further investigation of long-term, large-scale RCTs and the development of treatment protocols to define true outcomes and recurrence rates. Additionally, a major current limitation is that ICAs are invasive and painful, severely impacting patient compliance, alongside the risk of local adverse effects like skin atrophy and dyspigmentation. Future directions are focused heavily on creating new formulations, combination treatments and drug delivery systems to overcome these drawbacks, notably including the use of Laser-Assisted Drug Delivery (LADD), where fractional lasers create micro-channels to enhance the deep penetration of topical steroids, as well as developing advanced transdermal systems like microneedle arrays and nanocarriers for controlled and sustained delivery. Finally, leveraging advances in molecular understanding, research is progressing toward targeted molecular therapies that intervene in fibrotic pathways (e.g., TGF-β) and testing emerging options by pushing the field toward more effective, personalized medicine.

Conflict of Interest

Authors declare no conflict of interest.

Authors’ Contributions

All authors have contributed equally to this work and have reviewed and approved the final manuscript for publication.

Funding Details

None.

Acknowledgements

None.

Consent for Publication

Informed consent for publication was obtained from the patient involved in this case report, as documented in the manuscript.

Informed Consent Statement

Informed consent was obtained from the participant involved in this study.

Ethical Statement

Not applicable

Data Availability Statement

Not applicable

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