Chordomas are aggressive tumors that are thought to arise from remnants of the embryological notochord. They can arise along the ventromedial aspect of the sacrum, mobile spine, and clivus—with most cases occurring in the sacrum or skull base (1–3). Chordomas are divided into three histological subtypes including conventional, dedifferentiated, and poorly differentiated (4). The initial treatment of choice for chordoma is maximal safe resection, and radiation therapy in select cases. While gross total resection significantly prolongs the progression free and overall survival for patients with chordoma, extent of resection can be limited in cases where critical neurovascular structures are involved (5–7). In the setting of subtotal resection, focused radiation may be useful, but the high doses of radiation required raises the risk of radiation-induced injury to the brainstem and spinal cord (8). Despite surgery and radiation, many chordomas progress to become unresectable, or may be too diffuse for radiation.

While there is an urgent need for systemic therapy for patients with recalcitrant chordoma, efficacy of traditional chemotherapy against chordomas has not proven useful, and targeted molecular therapies thus far offer limited benefit (9). Few recent case reports and clinical trials have highlighted the use of immunotherapy for treatment of refractory chordomas. Though no strict guidelines exist, indications for the utilization of immunotherapy for chordoma have been limited to lesions that have been previously treated with surgery and radiation but have progressed to become radioresistant and unresectable. In this review, we summarize the results of these exploratory studies and discuss the potential future role of immunotherapy for chordomas.

The utilization of immunotherapy for chordoma is a critical area of future research, and so far, several case series and clinical trials have been reported using a variety of immunotherapy strategies (Figure 3). Among case reports and series, most patients received pembrolizumab or a similar immunotherapeutic agent targeting the PD-1/PD-L1 interaction. For most patients, this targeted immunotherapy resulted in tumor regression and symptom improvement for a few months until the tumor eventually progressed, and immunotherapy was halted. Methods of creating more sustainable responses with immunotherapy will be a necessary topic of future investigation. In rare patients, sustainable responses were seen, as one patient in a sarcoma clinical trial received vaccine of irradiated, autologous tumor and was recurrence free at 19-month follow-up (10). While limited recommendations can be suggested due to the literature being largely restricted to case reports and small case series, immunotherapy is being considered for progressive chordomas that are unresectable and have failed radiation in the past. When immunotherapy is employed, the PD-1/PD-L1 interaction has been utilized the most and may provide tumor control in a subset of patients. Further, adverse effects due to the immunotherapies reported in the literature are not common.

Despite the application of immunotherapy to many types of cancers, the relationship between immunotherapy response and tumor microenvironment is still being defined. Studies elucidating the immune microenvironment of chordomas have shown that PD-L1 is present in tumor associated lymphocytes, but not in chordoma tumor cells (19). Other studies have shown that chordomas that expressed galectin-9 were also associated with more locally aggressive behavior, which correlated with a lower functional status for the patients (20). The expression of both galectin-9 and PD-L1 are pro-apoptotic for tumor invading lymphocytes and may allow for the chordoma to escape the patient's anti-tumor immune response. Apart from tumor infiltrating lymphocytes expressing PD-L1/PD-1 and chordoma cells producing galectin-9, many chordomas may not be strongly immunogenic (20). For example, despite success with brachyury silencing in-vitro in preclinical models, in the clinical trial using a brachyury vaccine plus radiation, the vaccine arm had no benefit over the placebo arm regarding tumor progression and the trial was discontinued (18, 21, 22). Though early, the sarcoma clinical trial utilizing autologous tumor as a vaccine source led to PFS for 19 months in one chordoma patient (10). These studies have highlighted the benefit of studying the immune microenvironment of chordoma, and recent single cell genomics and spatial transcriptomics studies have revealed new understanding on how the immune system can be modulated in chordoma (23–25).

PD-1/PD-L1 targeted therapies holds promise as these proteins are often expressed in tumor associated lymphocytes (19, 20). For future directions with vaccines, apart from brachyury and autologous tumor vaccines, other proteins expressed in chordoma that have been thought to represent useful targets include S100 and epithelial membrane antigen. High molecular weight-melanoma associated antigen may be beneficial to target as its expression within the tumor has been to significantly increase the risk of death and metastasis in patients with chordomas (26, 27). Since chordomas are largely thought to not be highly immunogenic due to an absence of mutational burden, vaccine based therapies may be needed in addition to immune checkpoint inhibitors (28, 29). Despite promising targets and future steps regarding further exploration of immunotherapy in chordoma, the rare incidence of this entity makes it challenging to study for clinical trials where large numbers of patients are necessary. The molecular heterogeneity of chordoma and lack of widely accepted biomarkers to create molecularly informed clinical trials is also a limitation with current trial design in chordoma (30–33). Due to the challenges in studying the therapeutic efficacy in chordoma patients, there is a great emphasis on the development of preclinical models for laboratory-based testing. More cell lines and xenografts are being created among the chordoma research community, which are particularly important given the current lack of a chordoma mouse model.

Alternative methods for treating unresectable, radioresistant chordomas include targeted molecular therapy. Commonly reported molecular targets in chordoma include platelet derived growth factor (PDGFR), vascular endothelial growth factor receptor (VEGFR), and epidermal growth factor receptor (EGFR), insulin-like growth factors (IGF), and mammalian target of rapamycin (mTOR). PDGFR targeting agents include imatinib and dasatinib. In a phase II clinical trial in recurrent PDGFR positive chordomas, imatinib treatment resulted in stable disease for 70% of patients and the median PFS was nine months (34). Imatinib used in patients with recurrent PDGFR positive chordomas resulted in stable disease for 74% of patients and the median PFS was nine months (35). No patients had partial or total reduction in their tumor burden. Other studies have looked at molecular inhibitors that target PDGFR along with other receptors. One basket study looking at the efficacy of dasitinib; an inhibitor of PDGFR c-KIT, BCR-ABL, and ephrin receptor kinases; in chordoma found that the 6-month, 2-year, and 5-year overall survival for patients was 54%, 43%, and 18% respectively (36). In a series of four patients treated with pazopanib; which targets PDGFR, VEGFR, c-kit, and fibroblast growth factor receptor (FGFR); and sunitinib, which targets PDGFR and VEGFR, four patients were treated with pazopanib and had a mean PFS of 8.5 months. The one patient treated with sunitinib had radiographic regression of her metastatic chordoma and had disease stabilization for 27 months (37). EGFR targeted therapies utilized in advanced chordoma include lapitinib and erlotinib. In a phase II study, 33% of patients had partial response and 39% of patients had stable disease (38). Additionally, erlotinib has proven to be effective against chordoma that was previously recalcitrant to imatinib (39, 40). One study reports the use of lisitinib, an IGF-1 receptor targeting agent, in a patient with chordoma which resulted in stable disease for five years (41). Everolimus and imatinib have been used for patients who had chordomas resistant to imatinib monotherapy (42). At 12-months, 48.1% of patients experienced continued control of their chordoma. Of note, approximately 30% of patients discontinued therapy due to adverse events. Patients with chordoma resistant to imatinib monotherapy had favorable response to imatinib combined with sirolimus as 89% of patients had clinical benefit as defined by the RECIST criteria (43). While VEGFR targeting therapies including sorafenib and thalidomide have also been utilized, a high rate of adverse reactions precludes its frequent use in patients (37, 44). Conventional chemotherapies have not proven useful for chordoma (9).

Immunotherapy for chordoma is a promising area of investigation with increasing, but small, numbers of case series and clinical trials. Despite challenges in patient accrual, future directions in chordoma immunotherapy may lie in vaccine-based therapies and immune checkpoint inhibitors. Understanding chordoma heterogeneity and microenvironment will likely elucidate important chordoma features that will inform future clinical trial design.