Surgery represents the mainstay of treatment for patients with high-risk localized head and neck CSCC. Complete surgical margin assessment via Mohs micrographic surgery (MMS) or other peripheral and deep exhaustive margin assessment (PDEMA) techniques is recommended to achieve optimal outcomes [37]. MMS is performed by a trained physician who serves dual roles as both a surgeon and a pathologist. This procedure involves removing thin layers of skin and assessing the presence of cancer cells under microscopy; this process is repeated until clear margins are identified [38]. Advantages of MMS include intraoperative visualization of the entire excision margin and high rates of tissue preservation in cosmetically and functionally sensitive locations. MMS has been associated with improved outcomes, such as lower rates of local recurrence, nodal and distant metastasis, and disease-specific mortality compared to standard excision techniques [39,40]. Other PDEMA approaches differ from MMS in that they involve a team-based approach, in which the procedure is performed by a trained surgeon and the slides are reviewed by a pathologist. Like MMS, these PDEMA approaches have also been shown to have superior outcomes compared to standard excision when there is effective communication among the members of the multidisciplinary team and clear margins are obtained [41]. PDEMA approaches (i.e., Tubingen methods) are preferred over MMS when advanced lesions require excision under general anesthesia due to significant tumor size and/or depth of involvement, or when complex reconstruction is anticipated following removal [42].

A re-excision is recommended for positive margins following surgery. In cases where re-excision is not possible, then adjuvant RT or systemic therapy with immunotherapy is recommended. If negative margins are present following surgery, but extensive PNI or other high-risk features exist, then adjuvant RT is recommended. In the absence of high-risk features, when negative margins are obtained, continued surveillance is recommended, typically by dermatology (every 3–6 months for the first 2 years, every 6–12 months for the next 3 years, and then annually for life) [32].

Definitive RT may be indicated for patients who are poor surgical or immunotherapy candidates because of comorbidities or the extent of disease [32]. Additionally, RT may be indicated if resection would not achieve optimal disease control or if surgery could cause undesirable functional or cosmetic outcomes [43]. Previous studies have demonstrated widely varying recurrence rates ranging from 2.8%–42% following definitive RT, perhaps owing to various techniques or indications, with higher recurrence rates reported in T3/T4 tumors and immunosuppressed patients [44,45].

Adjuvant RT reduces the risk of disease recurrence and is typically indicated for patients with positive margins after surgery, lesions that cannot be fully re-excised, and tumors with PNI or other high-risk features [32]. In patients with positive margins following surgery, adjuvant RT has been shown to improve locoregional control and survival outcomes [46–48]. In patients with negative margins following surgery, adjuvant RT has demonstrated approximately a 50% reduction in local and nodal recurrence [49]. While RT is generally well tolerated, it is toxic. RT-related adverse effects can be classified into acute (≤6 months) or delayed (>6 months). Acute toxicities can persist for several weeks and range from mild erythema to desquamation and necrosis of skin. Delayed toxicities often manifest months or years after RT and may include fibrosis, skin atrophy, lymphedema, skin pigmentation changes, non-healing ulcerations, soft tissue or bone necrosis, or secondary cancers [50]. Due to the increased risk of complications, RT is not recommended for recurrent lesions in a previous radiation field. RT is contraindicated in patients with genetic conditions predisposing them to RT-induced skin cancer, such as nevoid basal cell carcinoma syndrome or DNA repair disorders such as xeroderma pigmentosum and Bloom syndrome. RT is relatively contraindicated in connective tissue diseases such as lupus or scleroderma [32].

There are no standardized chemotherapy regimens for the treatment of locally advanced or metastatic head and neck CSCC. Previously utilized cytotoxic chemotherapies include platinum (cisplatin, carboplatin), 5-fluorouracil, methotrexate, bleomycin, doxorubicin, and taxanes (paclitaxel, docetaxel). However, evidence regarding their efficacy is limited to single-arm studies and case series with modest response rates, short durations of response, and significant toxicity. Additionally, chemotherapy represents a major therapeutic challenge in older and frail patients [51,52]. A systematic review of patients with metastatic CSCC treated with cisplatin demonstrated an ORR of 45% with a median disease-free survival (DFS) of 14.6 months [53]. Given its limited efficacy and the increased risk for toxicity, the use of chemotherapy is recommended for patients with locally advanced or metastatic head and neck CSCC who are not candidates for curative surgery or RT and who are ineligible for immunotherapy or experience disease progression following ICI therapy [32].

EGFR inhibitors were one of the first systemic targeted therapies utilized in head and neck CSCC. The EGFR protein is a transmembrane protein, part of the receptor tyrosine kinase (RTK) family. When overexpressed, downstream signaling pathways such as Extracellular signal-related kinase (ERK) and Phosphoinositide 3-kinase/protein kinase B (PI3K/AKT) are activated, which promote cell survival [54–56]. EGFR overexpression is present in 43%–73% of head and neck CSCC cases and may be associated with worse outcomes [16]. EGFR inhibitors can be broadly classified based on their mechanism of action: monoclonal antibodies, which target the extracellular ligand-binding domain of RTK, or small tyrosine kinase inhibitors (TKIs), which inhibit the intracellular tyrosine kinase domain of RTK [57].

Cetuximab, a chimeric (mouse/human) monoclonal antibody, is the most well-studied EGFR inhibitor in head and neck CSCC. Its efficacy was evaluated in a phase 2 trial (NCT00240682) of 36 patients with CSCC. Patients were treated with an initial dose of 400 mg/m², followed by 250 mg/m² weekly for a minimum of 6 weeks. At a 48-week follow-up, the ORR was 28% (8 partial responses [PR] and 2 complete responses [CR]) [58]. Furthermore, a large retrospective study evaluated 58 chemotherapy-naïve patients with CSCC treated with cetuximab monotherapy and demonstrated an ORR of 42% and a disease control rate (DCR) of 70% at 12 weeks [59]. Panitumumab, a humanized monoclonal antibody, was evaluated in a phase 2 trial of 16 patients with advanced CSCC. Patients received a minimum of 3 cycles (6 mg/kg), and a 31% ORR was observed (3 PR and 2 CR) [60]. Dacomitinib is a second-generation small-molecule EGFR inhibitor (human epidermal growth factor receptor (HER) 2/4), which has previously demonstrated efficacy in head and neck SCC cell lines compared to cetuximab [61]. A phase 2 trial (NCT02268747) evaluated the use of dacomitinib in patients with recurrent or metastatic CSCC. The ORR was 28% (26% PR, 2% CR), and the DCR was 86% [62]. EGFR inhibitors are currently recommended for patients who are not candidates for ICIs or who experience disease progression despite ICI treatment [32].

Despite improved efficacy compared to chemotherapy, EGFR inhibitors are limited by their short duration of response (DOR) due to acquired resistance. Mechanisms of acquired resistance include: (1) point mutations in the EGFR protein, altering the ability of inhibitors to bind to their target (i.e., an S492R mutation, which interferes with cetuximab binding); (2) activation of alternative signaling pathways such as amplification of HER2 and Mesenchymal-epithelial transition factor (MET), and AXL receptor tyrosine kinase (AXL) overexpression; (3) mutations in downstream effectors KRAS, BRAF, and PI3K, leading to increased EGFR-independent signaling; and (4) immune evasion by downregulation of major histocompatibility complex-I (MHC-I) or increased programmed cell death ligand 1 (PD-L1) expression [63–65]. Strategies to overcome EGFR inhibitor resistance have included utilizing a synergistic approach by combining EGFR inhibitors with other standard therapies, such as chemotherapy or RT, to improve outcomes [66].

Given the demonstrated effectiveness of ICIs in the treatment of patients with advanced head and neck CSCC, there is now significant interest in their use in the neoadjuvant setting to improve outcomes. A potential benefit of a neoadjuvant ICI treatment approach may include a more robust immune response due to a tumor-in-situ, leading to enhanced T-cell expansion [86,87]. Additionally, there is the potential for reduction of tumor burden and improved resectability of tumors in anatomically and cosmetically sensitive locations. Possible disadvantages of neoadjuvant ICI treatment include a missed opportunity for curative intent with surgical resection in non-responders and the potential risk of irAEs, which may further delay surgery [86]. Of note, the rate of recurrence of very advanced head and neck CSCC after surgery could be as high as 30%, encompassing local, regional, and distant sites. There are no known biomarkers to direct treatment selection.

Neoadjuvant cemiplimab was evaluated in a phase 2 trial (NCT03565783) of patients with resectable stage III–IVa CSCC [79]. Twenty patients were treated with 2 cycles of IV cemiplimab (350 mg every 2 weeks) prior to surgery. Eleven patients were found to have a pCR and 3 patients had a major pathologic response (MPR). pCR is defined as the absence of residual tumor following neoadjuvant treatment and is often used as a surrogate endpoint in clinical trials [88]. MPR is defined as ≤10% residual tumor following neoadjuvant treatment [89]. Subsequently, a phase 2 study (NCT04154943) evaluated the use of up to 4 doses of IV cemiplimab (350 mg every 3 weeks) in 79 patients with resectable stage II–IV CSCC prior to surgery [80]. Notably, 51% of patients achieved pCR, and most patients (68%) who had a PR on imaging were found to have a pCR, suggestive of neoadjuvant cemiplimab’s therapeutic efficacy. In an extended follow-up analysis (median follow-up of 18.7 months), none of the 10 patients who achieved pCR were found to have disease recurrence at data cutoff. The estimated median event-free survival (EFS) rates at 12 and 24 months were 89% and 84%, respectively [90].

In conclusion, neoadjuvant cemiplimab demonstrates promising pathologic responses in head and neck CSCC. Further randomized phase 3 trials are accruing, such as NRG-HN014 (NCT06568172), to demonstrate improved OS prior to widespread adoption.

The rationale for an adjuvant ICI approach is to eliminate micrometastatic disease following curative treatment to improve survival outcomes. Several prospective trials have demonstrated the effectiveness of adjuvant ICIs in the treatment of resectable stage III/IV melanoma at high risk for recurrence, which has prompted interest in their use in head and neck CSCC [91–93]. One potential disadvantage of adjuvant ICI treatment is the risk for irAEs, some of which may be irreversible and contribute to increased morbidity and mortality [94].

The phase 3 KEYNOTE-630 trial (NCT03833167) had planned to investigate the use of adjuvant IV pembrolizumab (up to 9 cycles) in patients with high-risk, locally advanced CSCC; however, this trial was prematurely discontinued due to futility [95,96]. Additionally, the phase 3 C-POST trial (NCT03969004) investigated the use of adjuvant IV cemiplimab (up to 48 weeks) in 415 patients with high-risk locally advanced CSCC [97]. This study demonstrated significantly improved DFS with a 68% reduction in risk of disease recurrence or death following cemiplimab treatment compared to placebo (hazard ratio [HR]: 0.32; 95% CI: 0.20–0.51; p < 0.001) [98]. An OS benefit has not yet been demonstrated, although follow-up is ongoing. Further data analyses are needed prior to recommending adjuvant ICIs.

In conclusion, preliminary data regarding the use of adjuvant cemiplimab appear promising, but mature data from the C-POST trial are needed to assess whether there is a survival advantage.

Although ICIs have significantly improved outcomes in patients with head and neck CSCC, primary resistance remains a major therapeutic challenge, with approximately 40% of patients failing to respond to initial treatment.

Additionally, even among responders, acquired resistance can develop over time, further contributing to lower response rates [99]. Possible reasons for primary ICI resistance may include immunosenescence, which is common in older individuals and results in impaired ICI efficacy due to increased T-cell exhaustion, and a higher proportion of immunosuppressive cells within the tumor microenvironment (TME) [100–102]. The gut microbiome has also been implicated in modulating ICI responsiveness [103,104]. Tumor-intrinsic factors responsible for ICI resistance may include downregulation of human leukocyte antigen (HLA) expression and upregulation of alternative signaling pathways [105]. For instance, abnormal activation of the Wnt/β-catenin signaling pathway leads to decreased chemokine production, which results in impaired T-cell recruitment and infiltration, thus favoring an immunosuppressive TME [106]. Additionally, mutations in Janus kinase (JAK) signaling have been shown to impede interferon-γ signaling, resulting in impaired antigen presentation and T-cell-mediated cytotoxicity [107]. Tumor-extrinsic factors may include the increased presence of immunosuppressive cells within the TME, which impairs T-cell infiltration [99]. For example, perineural invasion was reported to be a mechanism of immune resistance to anti-PD-1 therapy via IL-6 and type I-interferon secreted by the injured nerve [108].

Finally, mechanisms responsible for acquired ICI resistance may be due to alterations in HLA expression and interferon-γ signaling, as well as impaired recognition of tumor antigen, further contributing to immune evasion [109], as suggested by the susceptibility of chronic lymphocytic leukemia patients to head and neck CSCC [108].

Given the challenges associated with ICI resistance in head and neck CSCC, current research has been directed toward combinatorial treatment strategies (through a synergistic approach) and novel targets to improve outcomes. One potential treatment approach is the use of ICIs in combination with RT. Previous studies have suggested that RT could enhance the effectiveness of ICIs by inducing the release of damage-associated molecular patterns (DAMPs) from tumor cells, leading to an augmented antitumor immune response via enhanced antigen presentation and T-cell priming [110]. The use of avelumab in combination with RT in patients with unresectable CSCC is currently being evaluated in the UNSCARRed study (NCT03737721) [111]. A second approach is to use EGFR inhibitors in combination with ICIs. EGFR inhibitors may promote a more inflamed TME through increased T-cell infiltration and activity, reduced immunosuppressive signals, and enhanced antigen presentation [82,112]. The single-arm multicenter phase 2 AliCe study (EudraCT 2018-001708-12) evaluated the use of avelumab (anti-PD-L1, 10 mg/kg every 2 weeks) in combination with cetuximab (500 mg/m² every 2 weeks) for up to 1 year in 54 patients with stage III/IV unresectable CSCC. A majority (66%) of patients in this study had received prior chemotherapy or anti-PD-1 treatment. Preliminary results were presented at the 2023 ESMO Congress: the median follow-up was 2.5 years, and the median PFS and OS among patients in the per-protocol cohort (n = 37) was 9.2 months and 25.4 months, respectively [113]. Additionally, 20% of patients experienced ≥grade 3 TRAEs, and 2 patients discontinued treatment due to AEs. Lastly, the multicenter phase 2 I-TACKLE trial (NCT03666325) evaluated the addition of cetuximab to pembrolizumab in 43 patients with locally advanced or metastatic CSCC, once these patients progressed on single-agent pembrolizumab [82]. Among patients exposed to pembrolizumab, an ORR of 44% (19/43) was observed. Of the 21 patients with disease recurrence, 8 (38%) responded to cetuximab despite developing primary resistance to pembrolizumab.

Despite the widespread use and availability of ICIs in the US, there are several economic and logistical barriers that preclude their administration in more resource-limited countries. First, ICIs are associated with significant financial costs, as the price for a 3-week cycle of dual ICI treatment for melanoma can soar to >$40,000 [114]. Second, considerable infrastructure is necessary to administer ICIs. For example, education and training are needed for medical providers; healthcare facilities must possess specialized equipment to screen eligible patients and monitor toxicity; and well-designed protocols need to be implemented to manage toxicity. Additionally, the lack of reliable supply chains further exacerbates the issue of drug availability. Strategies to improve access to ICIs may include re-evaluating dosing strategies to maximize cost-effectiveness, regional or global price negotiation, development of public-private partnerships, government subsidies, and enabling production of generic ICIs locally through arrangements with pharmaceutical companies to minimize disruption of the drug supply [115,116].

There are 5 clinical trials evaluating the use of ICIs in advanced head and neck CSCC. First, a phase 1 trial (NCT05085496) is evaluating the use of stereotactic body RT (SBRT) and atezolizumab (PD-L1 inhibitor) in patients with borderline resectable or unresectable CSCC [136]. This study is estimated to be completed in 2027.

Next, a phase 2 trial (NCT03737721) had planned to evaluate the use of RT and avelumab in patients with unresectable CSCC [111], however was terminated prematurely due to loss of funding. Third, the phase 2 Alliance A091802 trial (NCT03944941) is evaluating the use of avelumab +/− cetuximab in patients with advanced CSCC [137]. It is estimated to be completed in 2028. Additionally, a phase 2 trial (NCT04050436) is evaluating the use of cemiplimab +/− RP1 in patients with locally advanced or metastatic head and neck CSCC [138]. Initial results of this study were disclosed in a press release, in which combination therapy failed to meet either of the study’s primary endpoints (CR, ORR) [139]. It is estimated to be completed in 2025. Finally, a phase 2 trial (NCT04204837) is evaluating the use of nivolumab +/− relatlimab (anti-LAG-3) in patients with locally advanced or metastatic CSCC [140]. Results from the nivolumab cohort were presented at the 2022 ASCO Annual Meeting; among 29 evaluable patients, the best ORR observed was 65.2% along with a DCR of 66.7% and a median PFS of 10.9 months [141]. It is estimated to be completed in 2027.

There are 4 ongoing trials evaluating the use of neoadjuvant systemic ICIs in resectable head and neck CSCC. A single-arm phase 2 trial (NCT06288191) is evaluating the use of 2 cycles of neoadjuvant IV nivolumab (480 mg) and relatlimab (80 mg) every 4 weeks in patients with treatment-naïve resectable CSCC [143]. This study is estimated to be completed in 2036.

Next, the single-arm phase 2 DESQUAMATE trial (NCT05025813) is investigating the use of 4 cycles of IV pembrolizumab (200 mg every 3 weeks) in patients with resectable CSCC, followed by interval restaging, prior to surgery [144]. It is estimated to be completed in 2027.

Additionally, a single-arm phase 2 trial (NCT04315701) is investigating the use of neoadjuvant IV cemiplimab (up to 3 cycles) in patients with high-risk localized, locally recurrent, or resectable locally advanced CSCC. Patients may receive an additional treatment cycle if their disease is deemed unresectable after 3 cycles [145]. It is estimated to be completed in 2027. Finally, a phase 3 trial (NCT06568172, NRG-HN014) is evaluating the role of surgery +/− neoadjuvant cemiplimab (up to 4 cycles) in patients with CSCC [146]. It is estimated to be completed in 2031.

There are 2 ongoing trials evaluating adjuvant ICIs in resectable head and neck CSCC. First, the phase 3 C-POST trial (NCT03969004) evaluated the use of adjuvant cemiplimab vs. placebo in 415 patients with high-risk resectable CSCC [97]. 209 patients were assigned to the experimental arm and received IV cemiplimab 350 mg every 3 weeks for 12 weeks, followed by cemiplimab 700 mg every 6 weeks for up to 36 weeks. High-risk features in this study were defined as follows: (1) nodal disease with extracapsular extension (ECE) and at least 1 lymph node greater than 20 mm or ≥3 positive lymph nodes noted on surgical pathology, regardless of ECE; (2) in-transit metastases; (3) T4 lesion; (4) PNI; and (5) recurrent CSCC with ≥1 other risk factor [98]. The median follow-up was 2 years, and this study demonstrated improved DFS (HR 0.32, 95% CI 0.20–0.51, p < 0.001) along with decreased risk of locoregional and distant recurrence. OS data is not yet mature. The study is estimated to be completed in 2028. Additionally, a phase 1 trial (NCT04428671) is investigating the use of perioperative (neoadjuvant + adjuvant) cemiplimab for the treatment of high-risk localized CSCC. Patients will be treated for up to 3 cycles prior to surgery, and up to 18 cycles after surgery [147]. It is estimated to be completed in 2031.

There are 3 ongoing trials evaluating intralesional immunotherapy in the management of head and neck CSCC. First, a phase 1 trial (NCT06014086) is evaluating the use of 4 doses of weekly neoadjuvant intralesional PH-762 (anti-PD-1 mRNA) in patients with advanced cutaneous malignancies, including CSCC [148]. The study is estimated to be completed in 2026. Next, a phase 3 trial (NCT06585410) is evaluating the use of intralesional cemiplimab compared to surgery in patients with early-stage CSCC [149]. It is estimated to be completed in 2030. Finally, a phase 1 trial (NCT04163952) is evaluating the use of T-VEC and panitumumab (every 2 weeks, up to 3 cycles) in patients with locally advanced or metastatic head and neck CSCC [142]. It is estimated to be completed in 2025.