Ionizing radiation induces the generation of reactive oxygen species (ROS) that leads to oxidative stress (11). Antioxidant enzymes like superoxide dismutase (SOD), catalase (CAT), and glutathione peroxidase (GSH-Px) are activated to counteract the ROS. Excessive ROS production can overburden the oxidative defenses of the skin, causing damage to the biological macromolecules such as DNA, proteins and lipids (12). This oxidative damage triggers a cascade of events that contributes to skin injuries. For instance, UV radiations lead to the production of ROS in the epidermis and dermis that can also activates matrix metalloproteinases (MMPs). It leads to the degradation of the extracellular matrix (ECM), resulting in skin wrinkling.

Radiation exposure triggers a complex inflammatory response involving various chemicals mediators, cell types and signaling pathways (13). Damage associated molecular patterns (DAMPs) released from damaged cells recruit the immune cells to the site of injury, where they initiate and amplify the inflammatory response (12). These immune cells release inflammatory mediators, such as cytokines, which further exacerbate the inflammatory response (6). Pro-inflammatory cytokines, including IL-6, IL-1β, and TNF-α, play a crucial role in RISI. For instance, activated microglia release pro-inflammatory cytokines such as IL-6 and IL-1β that leads to neuroinflammation.

Excessive fibrotic remodeling can occur in the later stages of RISI. The release of growth factors and continuous inflammation can activate fibroblasts that leads to increased production of extracellular matrix (ECM) such as collagen (14). This causes remodeling of the (ECM) and the development of fibrosis, which can impair tissue function leading to chronic radiation induced skin injuries.

Radiation directly impacts the vasculature by endothelial cell injury and apoptosis. Vascular damage is a critical component in pathogenesis of RISI by causing senescence (15). Microvascular endothelial cells are particularly sensitive to ionizing radiation and radiation induced apoptosis. Exposure to ionizing radiations causes the release of oxygen radicals and proteases, resulting in leukocyte dysfunction, loss of endothelial barrier function that eventually leads to organ damage (16). In addition, radiotherapy can accelerate atherosclerosis, resulting in vascular events.

The nuclear factor erythroid 2-related factor 2 (Nrf2) is the primary regulator of the cellular antioxidant response (17). Activation of the Nrf2 pathway results in the expression of antioxidant and cytoprotective genes that helps to alleviate the oxidative stress, thereby offering protection against radiation induced injuries as described in Figure 3. Experimental studies have shown that Nrf2 deficient mice are more susceptible to RISI, underscoring the critical protective function of this pathway (4). Glycocalyx sialic acid has been found to modulate Nrf2 pathway in response to fluid shear stress in human endothelial cells which suggests a broader regulatory mechanism for Nrf2 activity (18).

The transforming growth factor-beta plays a crucial role in tissue fibrosis. TGF-beta promotes the differentiation of fibroblasts into contractile myofibroblasts and stimulate the overproduction of collagen, fibronectin, and other ECM components (19). In case of radiation injury, persistent TGF-β signaling contributes to the major hallmarks of late-stage RISI such as chronic inflammation, excessive ECM deposition and dermal fibrosis. This pathway has shown promise in preclinical model, where inhibition of TGF-β and downstream Smad signaling to reduce fibrosis in models of tissue injury and improve skin healing outcomes (20).

Pro inflammatory cytokines such as IL-1, TNF-α, and NF-κb are involved in sustaining inflammatory response within the skin (1). When skin cells such as keratinocytes, fibroblasts and immune cell are exposed to external stressors such as ultraviolet and ionizing radiations, they become activated and secrete these cytokines (21). These cytokines further contribute to skin damage and photoaging. The IR-induced ROS activate a critical signaling cascade, the mitogen activated protein kinase (MAPK) pathway. Activation of MAPK results in phosphorylation and release of transcription factors like ATF-2 and AP-1 (4). The transcription factor AP-1 binds to the promotor region of matrix metalloproteinases (MMP-1) which results in collagen fiber breakdown and results in wrinkled skin as seen in photoaging as shown in Figure 4.

One of the most widely used grading system for Radiation-Induced adverse reactions including skin toxicities is RTOG scale (9). It uses clinical symptoms such as erythema, edema and desquamation to qualitatively analyze the intensity of RISI. It is a clinician-based numerical classification from grade 0(no change) to grade 4(ulceration, necrosis). It is a basic and helpful system however it is not sensitive enough to observe any minute changes or the patient described symptoms.

In clinical trials, the clinicians typically use the National Cancer Institute (NCI)’s Common Terminology Criteria for Adverse Events to report the Adverse Events (AEs). The CTCAE also uses the clinician’s observations to grade the severity of symptoms and has five grades. The CTCAE is commonly used to grade the intensity of Acute Radiation Dermatitis (ARD) however, despite decades of clinical use, it has not been validated. The National Cancer Institute (NCI) designed the Patient-Reported Outcomes version of the Common Terminology Criteria for Adverse Events (PRO-CTCAE) to gauge clinical adverse events (AEs) directly from the patients participating in cancer clinical trials (22). By recording the patient’s viewpoint on the frequency, intensity, and interruption of symptoms to everyday life, it is meant to add to the commonly used Common Terminology Criteria for Adverse Events (CTCAE), which are reported by clinicians (23).

The RISRAS is a comprehensive grading scale (scoring between 0 to 36) integrating both the clinician-based and patient reported outcomes, especially devised to evaluate the skin symptoms related with radiation dermatitis (24). It enables the patients to report the intensity and implications of their skin reactions making it a patient-centered approach on RISI as detailed in Table 1.

These are the effects observed after or during therapy session. Acute radiation dermatitis is observed in all patients undergoing radiotherapy to some extent. Effective management of side-effects involves phase-specific strategy that revolves around prevention, symptom control and avoiding treatment interruptions.

During preventive measures, it is best to educate patients about their symptoms and expected side-effects so they can manage themselves without panicking. As the sensitive skin can be easily irritated so it is better to avoid irritants like perfumes, harsh soap, and wear loose clothing. Use lukewarm water and natural cleansers. Stay away from chemical-containing, irritants and strong products as these may flare-up the skin (33). Moisturizers and emollients should be used in daily routine to keep the skin hydrated and barrier functional, hyaluronic acid creams showed promising improvement in skin integration and hydration (34). If there is any inflammation on skin, topical corticosteroids like hydrocortisone can be applied to reduce inflammation and pruritus (optional). With many advancements in science, experimental agents (novel radioprotectors) are also available (e.g., Erb-IL10 fusion proteins, ROS scavengers) that can help in reducing inflammation or alleviating certain side-effects of radiotherapy or chemotherapy (34).

Chronic RISI can affect the patient’s quality of life drastically as the body weakens severely at this stage, involving persistent erythema, fibrosis, hyperpigmentation, telangiectasis, and ulceration on a long-term basis.

Hyaluronic Acid based formulations in gel or cream forms, are an effective wound dressing and proven for the localized treatment of cancer due to their hydrophilicity, biocompatibility, potential targeting property, and highly adaptable structure for modulated functionalities (43). As a fundamental component of the skin’s extracellular matrix, hyaluronic acid plays a vital role in key processes including tissue regeneration, angiogenesis, and inflammation (44). Hyaluronic acid released from the membrane stimulates wound healing by promoting re-epithelialization.

The Radiation Induced Skin Injuries are successfully managed using kangfuxin solution. Derived from an American Cockroach named Periplaneta americana, it has anti-ulcerative and wound healing properties. Kangfuxin has demonstrated potential in the treatment of oral mucositis and dermatitis caused by radiations. It reduces the intensity of desquamation and speeds up the healing process in patients undergoing radiation therapy (45–47).

Topical Corticosteroids are used for the treatment of Radiation Induced Skin Injuries (48). For atopic dermatitis, they are the first line of treatment (49). The use of TCs is potentially beneficial for managing radiation dermatitis by analyzing the randomized control trials and prospective studies on the use of TCs in radiation dermatitis (48). Topical corticosteroids efficiently alleviate the inflammation in a variety of skin disorders. Systemic Corticosteroids are also available but should be used carefully because of their severe adverse effects (50).

Preventive measures are crucial to reduce toxicity and to ensure therapeutic effectiveness during stereotactic body radiation therapy (SBRT) and proton therapy. These protocols are customized to the tumor site and patient-specific characteristics, including mobility management, dosage restrictions, imaging guidance, and toxicity mitigation strategies. Current practices from the literature are given below.

The foundation of SBRT safety lies in careful patient selection. A thorough evaluation of the tumor characteristics, patient comorbidities, and the proximity of the target volume to critical organs at risk (OARs) is carried out for this purpose. For example, SBRT is already an established treatment for early-stage, inoperable lung cancer but its role in high-risk prostate cancer is still under investigation (73).

The goal is to maximize the preservation of the surrounding healthy tissues while administering a high, conformal dosage to the tumor (72, 73). This includes inverse planning techniques. In proton SBRT, fewer beam angles can reduce low-dose radiation to normal tissues significantly compared to photon SBRT (74).

Safety protocols and quality assurance were much needed as these treatments involve high doses and short courses, giving rise to many challenges (75, 76). As compared to traditional radiation therapy, SBRT is associated with a higher risk of errors, ultimately requiring a need of robust safety protocols. The protocols include careful equipment commissioning, specialized staff training, and specific workflow differences in comparison to conventional radiotherapy (77).

Advancements in technology have encouraged the use of SBRT worldwide. Techniques like Volumetric Modulated Arc Therapy (VMAT), 3D Conformal Radiation Therapy (3DCRT), Intensity Modulated Radiation Therapy (IMRT), etc. are used to attain conformal dose delivery (75). The bar chart shown in the Figure 7 illustrates the percentage of centers using different Stereotactic Ablative Body Radiation Therapy (SABR) techniques (75). In the study of Mackonis, there is comparison of different SBRT techniques available and being used in different centers in NSW (New South Wales).

Prostate studies revealed that indeed SBRT is effective, but it can lead to acute gastrointestinal and genitourinary toxicities, which generally increase in the weeks following treatment and then stabilize (76). Genitourinary (GU) Toxicity Prevention: In an effort to reduce acute urinary retention, alpha-blockers can be prescribed (e.g., tamsulosin) during prostate SBRT (78).

Certain patient groups are at higher risk of severe radiation-induced skin injury (RISI).