Thyroid cancer (TC) is the most common type of malignant tumor in the endocrine system, which accounts for ~90% of all endocrine malignancies (1). Among the TC subtypes, anaplastic thyroid cancer (ATC) is extremely rare and represents only 1.7% of all TC cases (2). However, ATC is the most lethal TC subtype, with a high mortality rate (20–40 %) and poor prognosis (3). The average survival time is ~6 months and the 1-year overall survival (OS) rate is only 20% (4), largely due to the high invasiveness and resistance to treatment (5). Clinically, ATC often presents with a rapidly enlarging neck mass, frequently accompanied by dysphagia, hoarseness, dyspnea and occasionally neck pain (6). Metastasis is observed in 50% of patients, with the lungs, brain and bones as the most common sites of distant spread (7).

The core pathogenesis of TC involves genetic and epigenetic alterations, which include gene mutations, amplifications, copy-number gains, aberrant methylation, gene translocations, decreased expression of the Na/I symporter and non-coding RNA imbalances (8). Key molecular pathways implicated in TC are the MAPK and PI3K-AKT pathways (Fig. 1). Mutations commonly involve oncogenes such as BRAF (~60%), Ras (~13%) and rearrangements of anaplastic lymphoma kinase, rearranged during transfection (RET) and neurotrophic tyrosine receptor kinase genes (~5%), as well as loss-of-function mutations in tumor suppressor genes, such as peroxisome proliferator-activated receptor γ, PTEN and TP53 (~10%) (9,10).

Notably, ATC displays distinct genetic profiles compared with differentiated TC (DTC). The prevalence of telomerase reverse transcriptase (TERT) promoter and TP53 mutations in ATC are markedly higher compared with mutations in BRAF and Ras, which are less frequent in ATC. TERT promoter mutations are common in both poorly DTC and ATC, but TP53 mutations are more common in ATC and may serve a key role in tumor aggressiveness. Mutations in PTEN, PIK3CA and immune-modulatory genes [for example, programmed death ligand (PD-L)-1; PD-L2 and Janus kinase 2] are also relatively common in ATC (9–11). The higher overall tumor mutation burden in ATC contributes to the invasiveness and resistance to conventional therapies, including chemotherapy, radiotherapy and single targeted therapy, which makes ATC treatment highly challenging.

Current treatments for ATC include surgery, chemotherapy, radiotherapy, immunotherapy and targeted therapy. For cases without distant metastasis, complete surgical resection is the primary treatment and has demonstrated efficacy in early-stage tumors (12). As with the most common type of TC-papillary thyroid carcinoma, early surgical treatment without lymph node dissection still results in an extremely low recurrence rate within 8 years (13,14). However, ~80% of ATC cases were diagnosed with invasion of surrounding tissues, lymph node involvement or distant metastases, where surgery alone has a poor prognosis (4). In such instances, adjuvant therapies such as chemotherapy or radiotherapy are typically required. Chemotherapy often includes doxorubicin, cisplatin and paclitaxel (or docetaxel), administered either alone or in combination (doxorubicin + docetaxel or cisplatin + paclitaxel) (15). While the American Thyroid Association recognizes the survival benefits of chemotherapy in ATC, the survival rate for late-stage ATC remains dismal, as the median survival was only 2.7–3 months (4). Additionally, the notable off-target toxicities of chemotherapy drugs frequently lead to dose reductions or treatment discontinuation, which severely affect the quality of life in patients (16). Common adverse effects include cardiotoxicity from doxorubicin (17), ototoxicity, neurotoxicity and nephrotoxicity from cisplatin (17), peripheral neuropathy, gastrointestinal disturbances and hematologic toxicities from paclitaxel, with elderly patients being particularly vulnerable compared with younger patients (18). ATC is also generally unresponsive to radioactive iodine (RAI) therapy. Previous studies have reported that BRAF and TERT promoter mutations, which are prevalent in ATC (9,19), were associated with the loss of RAI avidity and impaired expression of thyroid-specific genes (20). These findings highlight the need for alternative therapeutic approaches.

Targeted therapy has become a promising area of research when conventional therapeutic approaches fail. Lenvatinib (E7080), a tyrosine kinase inhibitor (TKI) approved by the US Food and Drug Administration (FDA) and European Medicines Agency for progressive, RAI-refractory DTC, has demonstrated efficacy in the treatment of ATC (21,22). However, lenvatinib monotherapy has notable limitations, which include a high incidence of adverse events (AE) (23).

In the present review, the efficacy and safety of lenvatinib monotherapy and combination therapies for ATC were analyzed. The present review aimed to provide insights into the feasibility of various therapeutic combinations to improve survival outcomes and quality of life for patients with ATC.

The following search words were used for data mining in PubMed (https://pubmed.ncbi.nlm.nih.gov/.) and Web of Science (https://www.webofscience.com/) databases: {‘lenvatinib’ or all its synonyms [4-(3-chloro-4-((cyclopropylaminocarbonyl)amino)phenoxy)-7-methoxy-6-quinolinecarboxamide, E7080, Lenvima] in the Mesh database (Title/Abstract)} and [‘anaplastic thyroid cancer’ or all its synonyms (anaplastic thyroid carcinoma, anaplastic thyroid carcinomas, anaplastic thyroid cancers) in the Mesh database (Title/Abstract)]. Publications dated from 1st January 2024 to 7th February 2024 were imported into EndNote X9. After automatic elimination of duplicate documents, a total of 138 papers were obtained.

Inclusion criteria were as follows: i) Clinical trials of lenvatinib on ATC; ii) preclinical trials of lenvatinib on ATC; iii) clinical trial of lenvatinib combined with other drugs; and iv) preclinical trials of lenvatinib combined with other drugs on ATC. Exclusion criteria were as follows: i) Repeated literature and research; ii) irrelevant articles; iii) clinical trials of other TC types excluding ATC; and iv) preclinical trials of other types of TC excluding ATC.

Based on the aforementioned criteria, 42 studies were rejected (Fig. 2). The remaining 96 studies were examined and relevant materials were analyzed to extract the information and data required for the present review. After integrated analysis, the clinical efficacy and safety of lenvatinib and the combination with chemotherapy, radiotherapy, targeted therapy, immunotherapy and histone deacetylase inhibitors (HDACIs) on ATC were summarized. For the combination drugs that have not been clinically studied, the pre-clinical experiments were analyzed to assess their potential.

Lenvatinib is an oral, multi-target TKI that suppresses several key signaling pathways involved in tumor growth and angiogenesis. Lenvatinib targets include vascular endothelial growth factor receptor (VEGFR)1, VEGFR2 and VEGFR3, platelet-derived growth factor receptor (PDGFR)α, fibroblast growth factor receptor (FGFR)1, FGFR2, FGFR3 and FGFR4, mast/stem cell growth factor receptor, RET and the tumor angiogenesis-related proto-oncogene, receptor tyrosine kinase (c-KIT) signaling network, among others (24).

VEGF is a key cytokine in tumor neovascularization, which promotes tumor growth and cell proliferation. Upregulation of VEGFR was associated with increased tumor invasiveness and reduced recurrence-free survival. Among VEGFRs, VEGFR-2 served a pivotal role in tumor angiogenesis, while VEGFR-3 was key for lymph angiogenesis (27,28). By inhibition of the tyrosine kinase domain of VEGFR, lenvatinib disrupted intracellular signaling, which thereby suppressed tumor growth and migration (25–27).

PDGFR complements VEGFR in the mediation of angiogenesis. The PDGFRα signaling pathway has been identified as essential for cell migration and lenvatinib targets the PDGFRα pathway to impede tumor progression (28).

The FGFR family is upregulated in TC and regulates processes such as tumor cell proliferation, differentiation and survival (29). Lenvatinib exhibits notable potency against FGFR-1 by inhibition of the downstream effector, fibroblast growth factor receptor substrate 2 phosphorylation, which sets lenvatinib apart from other anti-angiogenic TKIs (imatinib, sorafenib), this ability may help overcome resistance to other angiogenesis inhibitors (30). FGFR-2 is the only FGFR detected in normal thyroid tissues and FGFR-2 expression is reduced in TC tissues (29). FGFR-3 was more highly upregulated in less aggressive TC types, whereas FGFR-4 was highly upregulated in more aggressive primary thyroid tumors, including ATC and PDTC, FGFR-4 was not upregulated in well-differentiated, less aggressive TC types (31). Thus, the FGFR family may be able to serve as a prognostic factor for patients with TC (32).

RET gene fusions are frequently observed in TC (33). Lenvatinib demonstrated antitumor activity in RET gene fusion-driven tumor models by blocking oncogenic signaling (34). The c-KIT receptor is suggested to serve a role in thyroid epithelial cell proliferation, but this function may be lost during malignant transformation. Lenvatinib inhibited tumor progression by targeting this pathway (Fig. 1) as well (34).

Lenvatinib has demonstrated efficacy in the treatment of various solid tumors, including liver cancer, renal cell carcinoma and adenoid cystic carcinoma. The role of lenvatinib in TC, particularly in ATC, involves disrupting tumor angiogenesis and growth through the aforementioned mechanisms. The present review focused on the development of lenvatinib and the effectiveness in managing ATC (35).

Tohyama et al (30) evaluated the antiproliferative effects of lenvatinib by comparing the half-maximal inhibitory concentration (IC₅₀) values in TC cell lines and Nthy-ori 3-1 cells (human thyroid follicular epithelial cells). Among 11 TC cell lines, only RO82-W-1 and TT cells demonstrated notable antiproliferative activity in vitro. However, in five ATC xenograft models, lenvatinib markedly reduced tumor micro vessel density, which suggested that the antitumor effects of lenvatinib in TC were primarily driven by antivascular activity.

Ferrari et al (36) investigated the effects of lenvatinib on primary ATC cells, 8305C cells and an ATC cell line (AF). Dose-dependent pro-apoptotic, anti-proliferative and inhibitory effects on migration and invasion were observed in primary ATC cells. Similar effects were seen in 8305C and AF cells, which attributed to the inhibition of EGFR, AKT and ERK1/2 phosphorylation. Lenvatinib also downregulated cyclin D1, a key regulator of cell cycle progression in ATC, which thereby suppressed tumor cell proliferation.

In vivo, lenvatinib reduced tumor growth, VEGF-A expression and blood vessel density in AF xenograft mice without affecting body weight. Additionally, while both lenvatinib and sorafenib inhibited subcutaneous ATC tumor growth, lenvatinib uniquely crossed the blood-brain barrier, which enabled intracranial tumor inhibition (37).

Clinical studies have demonstrated that lenvatinib monotherapy offers notable efficacy in the treatment of ATC, with PR rates ranging from 2.9 to 60%, DCR ranging from 25 to 100% and median OS ranging from 2.9 to 10.6 months. The difference in the PR, DCR and median OS rates may stem from the predominance of retrospective studies, which carry a high risk of selection bias, such as differences in enrollment criteria, sample sizes, prior treatments and demographic characteristics. For example: i) Age, poorer prognosis in trials with predominantly elderly participants (47); ii) sex; and iii) ethnicity, the initial recommended dose of lenvatinib (based on a phase III trial for RR-DTC) may not be optimal for Asian populations (77). Second, the external validity of retrospective studies is also questionable, as participants are often recruited from large single-center hospitals with more complex conditions. To address the aforementioned issues, it is essential to establish a standardized inclusion framework, recruit volunteers across multiple centers, dynamically adjust exclusion criteria and explore the optimal monotherapy dose under varying conditions. Third, the lack of predictive markers for ATC prognosis and lenvatinib efficacy. Previous studies have identified potential prognostic indicators, such as acute symptoms, white blood cell count, tumor diameter (≥5 cm), distant metastases, NLR, age >70 years and extra-thyroidal infiltration (T4b), which were associated with poor prognosis (78–80). Furthermore, a low NLR was associated with improved outcomes for lenvatinib-treated patients. Another potential predictive factor includes the presence of hand-foot syndrome, which was associated with improved a 24-month OS rate (81), and lower FGFR4 expression, which has been linked to better lenvatinib response (82). However, the lack of standardized detection methods, incomplete data collection and common selection biases require key interpretation of these results. Future research may employ more rigorous trial designs to validate these prognostic factors, which potentially leverage existing data to screen candidate biomarkers, establish uniform detection and enrollment criteria and conduct multi-center prospective validation trials.

Combination therapies including lenvatinib have demonstrated increased efficacy. For instance, in two studies investigating lenvatinib combined with pembrolizumab (64,75), the first study reported a DCR of 80% and a median OS of 18.65 months, while the second reported a DCR of 66% and a median OS of 17.3 months-substantial improvements compared with lenvatinib monotherapy. Additionally, a previous study that examined lenvatinib combined with paclitaxel and radiotherapy observed a median OS of 230 days, although the efficacy was lower compared with that of pembrolizumab combinations. Notably, conventional chemotherapeutic agents combined with lenvatinib yielded less favorable results (76), likely due to the late introduction of targeted therapies. Nevertheless, the combination of lenvatinib and pembrolizumab demonstrated robust potential. A recent consensus supported the effectiveness of lenvatinib and pembrolizumab combination therapy in patients with ATC with BRAF mutations (83). According to the Thyroid Neck Morbidity Complexity (TNMC) Scoring System (84), current guidelines (4,85) recommend surgery as the first-line treatment for patients with stage IVB BRAFv-ATC (TNMC, 0) with resectable primary tumors, followed by adjuvant radiotherapy and chemotherapy. The consensus recommended first-line use of BRAF/MEK inhibitors [dabrafenib-trametinib (DT)] for patients with stage IVB BRAFv-ATC or patients with unresectable or advanced disease (TNMC ≥1), followed by surgery. The consensus also advised combining the regimen with pembrolizumab from the outset or adding pembrolizumab upon disease progression. If surgery is not feasible after 6 months of neoadjuvant treatment, radiotherapy and chemotherapy should be considered. Similar to lenvatinib, combination therapy with pembrolizumab demonstrates survival benefits in patients with ATC. However, a previous study (69) indicated that prior resistance to TKI inhibitors notably limits the efficacy of pembrolizumab, while the consensus suggested that the limited effectiveness of adding pembrolizumab midway was due to the delayed onset of action. Additionally, combining pembrolizumab with immune checkpoint inhibitors increased treatment toxicity (64). Therefore, clinical decisions should be individualized based on the condition of the patient. For patients with stage IVC BRAFv-ATC, both the guidelines and consensus recommended routine DT plus pembrolizumab (DTP), with reassessment after 2–3 months. If surgery is not possible or recurrence risk is high, DTP should be continued. If surgery is resectable, DTP should continue postoperatively and discontinuation of pembrolizumab after 1 year may offer enhanced survival benefits.

Targeted therapy combined with immunotherapy is a promising direction for the future treatment of ATC. However, several clinical studies (44,45,86,87) on combination therapies are single-arm phase II trials with low levels of evidence, which potentially overestimate treatment efficacy. Future studies should incorporate control groups for causal inference, avoid selecting only patients with favorable baseline characteristics and extend follow-up duration to improve long-term safety data collection.

ATC remains one of the most challenging malignancies in TC, with limited benefits from traditional treatments (16,17,86–93). Targeted therapies such as lenvatinib represent a vital avenue for improving patient outcomes (Table I) (23,38,41,44,45,47,49,86,87,91–93). The present review highlighted the efficacy and safety of lenvatinib as both a monotherapy and in combination regimens. There are still several directions worth exploring in the future. Notably, lenvatinib has exhibited superiority to sorafenib in preclinical models of ATC brain metastases and has provided notable survival benefits in patients with ATC lung metastases (37,39). Combination regimens have also proven effective in mitigating toxicity, with specific combinations that demonstrate sensitivity in certain ATC subgroups. For example, lenvatinib combined with the BRAF inhibitor vemurafenib or HDACIs increased RAI sensitivity and lenvatinib combined with vinorelbine or HDACIs reduced drug resistance (52,68). However, relevant studies remain scarce, with most evidence derived solely from animal models and lacking clinical validation. Future research is warranted to verify the aforementioned hypotheses and provide improved therapeutic options for specific ATC subgroups.

The findings from the aforementioned studies highlight promising directions for future clinical trials, aimed at optimizing lenvatinib combinations to enhance DCRs, minimize toxic side effects and improve survival outcomes for patients with ATC. The present review serves as a foundation for future research and clinical trial design, with the ultimate goal of developing individualized therapies to meet the diverse needs of patients with ATC.