Summary

Background: Most cancer patients present resistance to immune therapy; only approximately 15% of patients respond to immune checkpoint inhibitors (ICI). Strategies able to increase ICI response are thus of great interest. Radiotherapy (RT), by acting as an immunomodulator is a good candidate to increase the proportion of ICI responders. However, RT dose and ultimate efficacy are limited by potential toxicity to healthy tissues. NBTXR3, a first in class radioenhancer administered by intratumoral injection, has been designed at the nanoscale to increase RT energy dose deposition within the tumor. The result is increased radiation-dependent tumor cell killing, without increasing radiation exposure of healthy tissues. Preclinical and early clinical data suggest NBTXR3 activated by RT can increase the anti-tumor response yielding both local and systemic (abscopal) effects. We hypothesize that NBTXR3 activated by RT, in combination with anti-PD-1 therapy (R3/RT/PD-1), will act synergistically to maximize the local RT effect while also producing a systemic effect sufficient to increase the proportion of ICI responders or convert ICI non-responders to responders.

Methods: NANORAY-1100 [NCT03589339] is a multicenter, open-label, phase 1 study to evaluate safety and tolerability of R3/RT/PD-1 in three cohorts: (1) Locoregionally recurrent or recurrent and metastatic head and neck squamous cell carcinoma (HNSCC) amenable to re-irradiation of the HN field, (2) Lung metastases from any primary cancer eligible for anti-PD-1, or (3) Liver metastases from any primary cancer eligible for anti-PD-1. Approximately two-thirds of each cohort will be composed of anti-PD-1 non-responders and one-third will be anti-PD-1-naïve. NBTXR3 injection volume is based on a percentage of gross tumor volume (GTV) determined by central review. The primary objective is to determine R3/RT/PD-1 RP2D. Secondary objectives are to evaluate anti-tumor response (objective response rate; ORR) of R3/RT/PD-1, safety and feasibility of NBTXR3 injection, and NBTXR3 body kinetic profile. Exploratory objectives will assess biomarkers of R3/RT/PD-1 response, including PD-L1 status by IHC, mRNA and cytokine immune marker profiling.

Summary

Background: The majority of cancer patients are resistant to immune therapy; only around 15% respond to immune checkpoint inhibitors (ICI). Thus, strategies able to increase ICI response are of great interest. Recent work suggests radiotherapy (RT) can act as an immunomodulator to increase the proportion of ICI responders and improve clinical outcomes. However, RT dose and ultimate efficacy are limited by toxicity related to exposure of healthy tissues. NBTXR3 is a first-in-class radioenhancer administered by intratumoral injection, designed at the nanoscale to increase RT energy dose deposition within the tumor. The result is increased radiation-dependent tumor cell killing, without increasing radiation exposure of healthy tissues. Preclinical and early clinical data suggest NBTXR3 activated by RT can increase the anti-tumor immune response, producing both local and systemic (abscopal) effects. We hypothesize that NBTXR3 activated by RT, in combination with anti-PD-1 therapy (R3/RT/PD-1), will act synergistically to maximize the local RT effect while also producing a systemic response sufficient to increase the proportion of ICI responders or convert ICI non-responders to responders.

Trial Design: NANORAY-1100 [NCT03589339] is a multicenter, open-label, phase 1 study to evaluate safety and tolerability of R3/RT/PD-1 in three cohorts: (1) Locoregional recurrent or recurrent and metastatic head and neck squamous cell carcinoma (HNSCC) amenable to re-irradiation of the HN field, (2) Lung metastases from any primary cancer eligible for anti-PD-1, or (3) Liver metastases from any primary cancer eligible for anti-PD-1. Approximately two-thirds of each cohort will be composed of anti-PD-1 non-responders. NBTXR3 injection volume is based on a percentage of gross tumor volume (GTV) determined by central review. The primary objective is to determine R3/RT/PD-1 RP2D. Secondary objectives are to evaluate anti-tumor response (objective response rate; ORR) of R3/RT/PD-1, safety and feasibility of NBTXR3 injection, and NBTXR3 body kinetic profile. Exploratory objectives will assess biomarkers of R3/RT/PD-1 response, including PD-L1 status by IHC, mRNA and cytokine immune marker profiling.

Summary

Purpose: First in class hafnium oxide nanoparticles (NBTXR3) activated by radiotherapy (RT) increase radiation dose deposit within cancer cells compared to RT alone. Given that RT can prime an anti-tumor immune response we hypothesized that this response could be enhanced by NBTXR3+RT in both animals and humans.

Method & Materials: Different abscopal assays in mice were conducted. Immunocompetent mice were injected in both flanks with murine tumor cells. Intratumoral injection of NBTXR3 (or vehicle) was performed in right flank tumors, followed by RT of right flank tumors only. Tumor growth was followed and immune cell infiltrates were analyzed by immunohistochemistry (IHC). Some mice received anti-PD-1 injections and tumor growth was monitored. Pts with locally advanced soft tissue sarcoma (STS) [NCT02379845] received either NBTXR3+RT or RT alone. Pts pre- and post-treatment tumor tissues were analyzed by IHC and Digital Pathology for immune biomarkers.

Results: Animal studies demonstrated that NBTXR3+RT induces an immune response which was not observed with RT alone. IHC showed significantly more CD8+ cells present in NBTXR3+RT treated and untreated tumors. Furthermore, NBTXR3+RT improved the effect of anti-PD-1. Similarly, increased CD8+ T cell infiltration pre- vs post-treatment was observed in tumor tissues from STS pts treated with NBTXR3+RT. An increase in biomarkers, including CD8, following NBTXR3+RT was also observed by IHC in tumor samples from STS pts compared to RT alone.

Conclusion: These results demonstrate that NBTXR3+RT induces a specific adaptive immune profile in both mice and STS pts. NBTXR3+RT also improved response to anti-PD-1 in mice, opening the potential for combination with immunotherapeutic agents in humans. We have therefore sought to investigate the safety and systemic effect of NBTXR3 activated by stereotactic ablative radiotherapy (SABR) in combination with anti-PD-1 in pts with locoregionally recurrent or metastatic (lung or liver) head and neck squamous cell carcinoma, as well as in metastatic non-small cell lung cancer and liver metastasis pts [NCT03589339].

Clinical Relevance & Application: The results of this study highlight the potential of NBTXR3 to be used in combination with immune checkpoint inhibitors in order to improve patient outcomes.

Summary

Background: Soft tissue sarcoma (STS) is a large and heterogeneous group of malignant mesenchymal neoplasms characterized by a strong tendency toward local recurrence and metastatic spreading. Consistently, the immune microenvironment in sarcomas is highly variable. A new class of material with high electron density, hafnium oxide, was designed at the nanoscale to efficiently absorb ionizing radiation from within the tumor cells and augment the dose deposited to a tumor. […]

Material and Methods: Tumor tissues pre- (biopsy) and post-treatment (resection) are collected from patients with locally advanced STS (NCT02379845), who received either HfO2-NP activated by RT or RT alone. Immunohistochemistry and Digital Pathology for immune biomarkers and Pan-Immune gene expression profiling are analyzed.

Results: A significant increase of CD8+ T cells and a marked increase of CD3+ and PD-1 T cells and CD103+ immune cell infiltration post- vs pre-treatment are observed for HfO2-NP + RT while not differences are seen for RT alone (more than 10 patients analyzed in each arm). Functional analysis of genes expression up-regulated in HfO2-NP + RT post- vs pre-treatment shows an enrichment of cytokine activity (IL7, IFNA, IL11, IFNG), adaptive immunity (RAG1, TAP1, TAP2, TBX21, IFNG, LTK, CD37, CD22) and T cell receptor signaling pathway (CD28, CTLA4, CD274, BTLA, TIGIT, CD5, ZAP70) when compared to RT.

Conclusions: Promising results are observed in patients who received HfO2-NP + RT in terms of immune cells infiltration post- vs pre-treatment when compared to RT. […]

Summary

Background: Radiation therapy (RT) has demonstrated ability to augment antitumor immunity, promoting immunogenic cell death (ICD) and stimulating immune adjuvant effects. On the other hand, RT has also been reported to induce immunosuppressive responses. A new class of material with high electron density, hafnium oxide, was designed at the nanoscale (HfO2-NP) to efficiently absorb ionizing radiation and augment the radiation dose
deposited from within the tumor cells. […]

Methods: The potential ability of HfO2-NP exposed to RT to transform tumors into immunologically active lesions was tested in vitro and in vivo. In vitro, the level of ICD markers was evaluated in a panel of human cancer cell lines, following cells treated or not with HfO2-NP and irradiated. In vivo, a vaccination assay was performed to evaluate the host immune responses in immunocompetent mice inoculated with murine CT26 cancer cells treated or not with HfO2-NP and irradiated with 6 Gy. […]

Results: Higher DAMPs levels (cell surface expression of calreticulin, extracellular adenosine triphosphate level and extracellular high-mobility group box 1 level) were observed in the tested cancer cells treated with HfO2-NP + RT when compared to cancer cells exposed to RT. […]

Conclusions: These results suggest an efficient cell killing (ability to generate ICD) with superior potential of HfO2-NP + RT to transform the tumor into an effective in situ vaccine when compared to RT. Moreover, HfO2-NP treatment generates a marked increase of immune cells infiltration in the tumors suggesting that it may convert immunologically “cold” tumor into “hot” tumor and could be combined with immunotherapeutic agents across oncology.

Summary

NBTXR3 exposed to irradiation enhanced cancer cells destruction and immunogenic cell death compared to irradiation alone, suggesting a strong potential for transforming tumor into an effective in situ vaccine. This may contribute to transform “cold” tumor into “hot” tumor and effectively be combined with most of the immunotherapeutic agents across oncology.