Summary

Purpose/Objective(s): Elderly and/or frail patients (pts) with head and neck squamous cell carcinoma (HSNCC) remain a challenging to manage and neglected population regarding clinical trials and data generation to support treatment choices. Despite representing 20% of the HNSCC population no consensus exists on what is the optimal treatment for these pts with locally advanced (LA) disease, vulnerable to treatment-induced toxicities with the current standard of care. New approaches are needed to improve clinical outcomes without adding toxicity. NBTXR3 hafnium oxide nanoparticles injected intratumorally may represent such an option. Otherwise inert; this first-in-class radioenhancer, augments the radiotherapy (RT) dose within tumor cells when activated by RT, increasing tumor cell death compared to RT alone. The results presented here demonstrate the feasibility and safety of NBTXR3 activated by RT in elderly/frail patients, a population with few therapeutic options.

Materials/Methods: Elderly/frail pts received a single intratumoral injection of NBTXR3 and intensity modulated radiation therapy (IMRT; 70 Gy/35 fractions/7 weeks). The study was a 3 + 3 dose escalation to test the NBTXR3 dose equivalent to 5, 10, 15, and 22% of baseline theoretical tumor volume, followed by a dose expansion. Primary endpoints include Recommended Phase 2 Dose (RP2D) determination and early dose limiting toxicities (DLT). NBTXR3 presence in surrounding healthy tissues and anti-tumor activity (RECIST 1.1) were also evaluated.

Results: Enrollment was completed at all dose levels: 5% (3 pts), 10% (3 pts), 15% (5 pts), and 22% (8 pts). No early DLT or SAE related to NBTXR3 or injection were observed. One G1 AE (asthenia; 22%) related to NBTXR3 and four AEs (G2 oral pain, G1 tumor hemorrhage, asthenia, and injection site hemorrhage) related to injection were observed. RT-related toxicity was as expected with IMRT. The RP2D was determined to be 22%. CT-scan assessment demonstrated localization of NBTXR3 intratumorally without presence in surrounding healthy tissues. At a median follow-up of 231 days, 9/13 (2 unconfirmed) evaluable pts receiving doses ≥10%, achieved a complete response of the treated tumors. The final dose escalation safety and efficacy results will be presented herein.

Conclusion: NBTXR3 was well tolerated at all tested doses and demonstrated preliminary anti-tumor activity. A dose expansion phase at the RP2D is ongoing. These results highlight the potential of NBTXR3 as a novel treatment option for elderly/frail pts with LA HNSCC and address an unmet medical need.

Summary

Purpose/Objective(s): The medical community faces important challenges to treat liver cancer because of underlying disease. Reduction of healthy tissue irradiation while at the same time increasing energy dose deposit within tumor cells still constitutes a challenge in radiation oncology. NBTXR3, hafnium oxide nanoparticles, increase energy deposit inside tumor cells only when activated by ionizing radiation such as stereotactic body radiotherapy (SBRT) and thus increase tumor cell death compared to radiation alone. Patients (pts) with hepatocellular carcinoma (HCC) or liver metastasis (mets) may benefit from the physical mode of action of NBTXR3, which does not engage liver and renal functions. A phase I/II clinical trial was conducted to evaluate NBTXR3 activated by SBRT in these pts [NCT02721056].

Materials/Methods: The Phase I part follows a 3+3 dose escalation design with dose levels of NBTXR3 corresponding to 10, 15, 22, and 33% of the baseline tumor volume. Pts were treated with a single NBTXR3 intralesional injection (ILI) followed by SBRT (45 Gy / 3 fractions / 5 to 7 days). Primary endpoints included identification of the recommended phase II dose(s) and early DLTs. Secondary endpoints included assessment of global safety profile, liver function evaluated by Child-Pugh score (CPS), AST to Platelet Ratio Index (APRI), and response rate (mRECIST/RECIST 1.1).

Results: Four levels of the dose escalation part are finalized (n=17): 6 pts at 10% (2 SBRT doses tested due to organs constraints), 4 pts at 15 and 22% (due to fiducial displacement and ILI shift) and 3 pts at 33%. No NBTXR3 related early DLT or SAE were observed. Indeed only one NBTXR3 related AE (G1 fatigue at 33%) was reported. There were no significant changes in CPS or APRI post-treatment. CT-scan assessment demonstrated absence of NBTXR3 leakage in surrounding tissues. Among 7 evaluable HCC pts, best mRECIST target lesion responses were: 3 CR, 4 PR. Among 5 evaluable mets pts, best target lesion responses were: 2 PR, 1 SD, 2 PD.

Conclusion: NBTXR3 was well tolerated up to the 33% dose level and demonstrated a very good safety profile. The very good tolerance and preliminary anti-tumor effects have supported a protocol amendment to study an additional higher NBTXR3 dose level (42%). Indeed recent data reinforces this further escalation as OS and local control seem to depend on RT dose and tumor volume. Liver dysfunction is the limiting factor for treatment in these pts, hence, this innovative physics based approach may constitute a valuable solution for pts with unresectable liver tumors. NBTXR3 showed statistically superior efficacy over RT alone in a phase II/III trial in soft tissue sarcoma [NCT02379845] and is currently being evaluated in phase I/II trials: head and neck [NCT01946867; NCT02901483], prostate [NCT02805894] and rectal cancers [NCT02465593].

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

Recent results of a phase II/III in locally advanced Soft Tissue Sarcoma patients demonstrated clinical benefits of intratumorally injected HfO2-NP activated by radiotherapy compared to radiotherapy alone, validating their first-in-class mode of action. In addition, animal studies have reported that HfO2-NP+RT can induce an abscopal effect, where RT alone cannot. Here, using a mouse abscopal assay, we measured T cells infiltrates in treated and untreated tumors after HfO2-NP intratumor injection and activation with RT, and their role in the abscopal effect.

These data indicate that the immunogenic conversion of the tumor microenvironment triggered by HfO2-NP+RT generates the abscopal effect by activation of CD8+ T cells. HfO2-NP+RT may potentiate a pro-inflammatory microenvironment appropriate for enabling an anti-tumor immune response. It may act as effective in-situ cancer vaccine and be combined with immunotherapeutic agents across oncology.

Summary

Background: Hafnium oxide, an electron-dense material, was designed at the nanoscale to increase the radiation dose deposited from within the cancer cells: “Hot spot” of energy deposit where the nanoparticles are when exposed to radiation therapy (RT). Preclinical studies have demonstrated increase of cancer cells killing in vitro and marked antitumor efficacy in vivo with presence of these nanoparticles (HfO2-NP) exposed to RT, when compared to RT alone. […]

Material and Methods: CT26 (murine colorectal cancer cells) were subcutaneously injected in the flank of BALB/c mice. Once the mean tumors volume reached 115±30 mm3, tumors were intratumor injected with HfO2-NP and irradiated with 2Gyx3 or 4Gyx3, or irradiated only. Tumors were collected 5 days after the last RT fraction and analyzed for immune cell infiltrates by immunohistochemistry (2Gyx3 and 4Gyx3) and cytokines content by flow cytometry (2Gyx3). […]

Results: In mice bearing CT26 tumors, a marked increase of cytokines content and immune cell infiltrates was observed with HfO2-NP + 2Gyx3 when compared to RT alone. The tumor immune cell infiltrates were
further enhanced with HfO2-NP + 4Gyx3. In mice inoculated with 4T1 cells treated with HfO2-NP + 40Gy, a marked increase of immune cell infiltrate (CD8+) was observed in tumors when compared to tumors in mice inoculated with 4T1 cells treated with 40Gy and control.

Conclusions: These in vivo data generated from CT26 and 4T1 tumor models suggest that HfO2-NP + RT triggers immunogenic conversion of the tumor microenvironement when compared to RT alone. HfO2-NP treatment may represent a therapeutical approach for broad applications since it does not rely on any molecular characteristics of the tumor.

Summary

Background: Between 70 to 90% of patient have « cold » tumors, i.e. devoid or poorly infiltrated by immune cells, rendering inoperative their treatment by immune checkpoint inhibitors. To allow these patients to benefit from these therapies, it is fundamental to prime an antitumor immune response. Radiotherapy (RT) has demonstrated its ability to induce the immunogenic cell death (ICD), a crucial event allowing the priming of the antitumor immune response. Meanwhile, a new class of material with high electron density, hafnium oxide, was designed at the nanoscale (HfO2-NP) to efficiently absorb ionizing radiation and increase the radiation dose deposition from within the tumor cells and increase killing of cancer cells. Here, we compared the ability of HfO2-NP and RT to RT alone to kill cancer cells and induce immunogenic cell death.

Methods: A panel of human and mouse cancer cell lines (mesenchymal and epithelial origin, radiosensitive and radioresistant) were treated or not with HfO2-NP, then irradiated by X-rays. Impact of the treatments on apoptosis and necrosis was assessed by FACS analysis (Annexin V/Propidium iodide). […]

Results: For all the tested cell lines treated with HfO2-NP and RT, a marked increase of apoptosis and necrosis was demonstrated, compared to cells treated with RT alone. In addition, higher levels of DAMPs (ecto-CRT, ecto-HSP70, ecto-HSP90, secreted ATP and extracellular HMGB1) were measured in the cancer cells treated with HfO2-NP and RT when compared to cancer cells exposed to RT.

Conclusions: HfO2-NP has demonstrated its capacity to kill cancer cells more efficiently than radiotherapy alone. HfO2-NP, administered via a single intratumor injection, is currently evaluated in clinical trials including soft tissue sarcoma (phase II/III), head and neck, prostate, liver and rectum cancers (phase I) and would permit to improve the local control of tumors, a crucial parameter for the cure and survival of patients. […]

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

Background: Functionalized hafnium oxide nanoparticles (NBTXR3) have been developed as selective radioenhancers, which may represent a breakthrough approach for the local treatment of solid tumors. The high electron density of the nanoparticles, when exposed to radiotherapy (RT), allow the absorption/deposition of a high radiation dose within the tumor cells, to physically kill the cells and possibly improve outcome. A phase I trial was implemented for the treatment of locally advanced HNSCC in patients (pts) older than 65 years who cannot receive cisplatin.

Methods: Pts received a single intratumor (IT) injection of NBTXR3, volume dose levels escalated at 5%, 10%, 15% and 22% of baseline tumor volume, followed by RT (IMRT, 70Gy/ 35 fractions / 7 weeks). Primary endpoints included feasibility of the IT implantation and safety. Secondary endpoints included IT residency of NBTXR3 using CT scan and RECIST 1.1 response.

Results: Enrollment was completed for volume 5%, 10%, and 15% (11 pts) and 1 patient at volume dose level 22%. Feasibility of the IT injection was confirmed. The treatment was easily administered, was safe with no SAE, or early DLT, which allowed the pts for completion of the planned RT schedule. Adverse events related to the injection procedure included grade 1-2 injection pain (1 pt), and tumor hemorrhage (1 pt). Results demonstrated that a single injection of NBTXR3 provides adequate bioavailability of NBTXR3 IT over seven weeks of RT. No leakage of NBTXR3 to the adjoining healthy tissues was observed. Preliminary results of antitumor activity according to RECIST 1.1 are presented below: 11 evaluable pts, 10 showed complete or partial response (RECIST 1.1) including, 1/5 complete response at dose levels ≤ 10% and 3/6 complete responses at dose levels > 10% Follow up results with duration of response and tolerance will be disclosed.

Conclusions: Injection of NBTXR3 was safe and well tolerated. All pts received the planned RT.

Summary

Nanomedicines are mainly used as drug delivery systems; here we evaluate a new application – to inhibit a drug’s metabolism thereby enhancing its effective dose. Micelles containing the natural furanocoumarin 6′,7′ dihydroxybergamottin (DHB), a known CYP450 inhibitor, were developed to transiently block hepatic CYP450-mediated drug metabolism and increase the bioavailability of the oncology drug docetaxel. Administered in mice 24 h prior to the drug, DHB-micelles enhanced antitumor efficacy in the tumor xenograft models HT-29 and MDA-MB-231, when compared to the drug alone. These DHB-micelles have similar composition to marketed docetaxel–micelles for human use. Despite not being optimized in terms of targeting hepatocytes, they do represent the first injectable example of nanosized metabolism-blocking agents and open the way for further work on such nanomedicines in man.