Window-of-opportunity study of ONC201 in pediatric patients with diffuse intrinsic pontine glioma (DIPG) and thalamic glioma

TPS2082

Background: H3 K27M-mutant diffuse midline glioma is a universally fatal malignancy primarily affecting children and young adults; while radiotherapy (RT) provides transient benefit, no effective systemic therapy is currently available. ONC201, a first-in-class imipridone, is an oral, blood-brain barrier penetrating, selective small molecule antagonist of dopamine receptor D2/3 and agonist of the mitochondrial protease ClpP. Previously, ONC201 monotherapy demonstrated durable objective responses in adults with recurrent H3 K27M-mutant glioma. This phase 1 trial was designed to evaluate ONC201±RT in pediatric patients with H3 K27M-mutant midline glioma DIPG. Methods: This multicenter, open-label, dose escalation and expansion phase 1 study of ONC201 is comprised of eight arms that will evaluate the recommended phase 2 dose (RP2D) of ONC201, biomarkers, and pharmacokinetics (PK) of ONC201±RT in various treatment settings. Arm G previously defined the RP2D for ONC201 administered twice weekly on consecutive days in patients with H3 K27M-mutant glioma who had completed radiotherapy. Arm H, for which enrollment is ongoing, will estimate the influence of tumor location and blood-brain barrier integrity on PK and intratumoral ONC201 exposure in biopsy-eligible pediatric tumors (DIPG or contrast-enhancing thalamic glioma). Patients eligible for Arm H will be aged 2-≤19 years, ≥2 weeks from last RT administration, and have a Karnofsky/Lansky performance score ≥50; prior confirmation of H3 K27M mutation is not required. In Arm H, single-agent ONC201 administration will occur on two consecutive days each week during each 21-day cycle at the RP2D defined in Arm G. Evidence of disease progression is not required; as such, ONC201 may be administered in the maintenance setting or for recurrent disease. Arm H has a planned enrollment of 27 patients. Each patient will undergo biopsy at a single prespecified biopsy window, which will be assigned at enrollment (Table); plasma for PK analysis will be collected from all patients at all time points shown in the Table, with additional collection pre-dose and 0.5 h post first dose. Clinical trial information: NCT03416530. [Table: see text]

Predicting CNS penetration of precision medicine therapies in oncology: A comparison of the CNS TAP tool and the BOILED-Egg computational model

2062

Background: The number of available targeted therapies has vastly expanded in recent years; however, only a selection of such therapies achieve adequate central nervous system (CNS) penetration. The CNS Targeted Agent Prediction (CNS TAP) Tool was developed to aid in the selection of precision medicine therapies based on preclinical data, clinical data, patient-specific genomic data, and importantly, optimal blood brain barrier penetration. Using a standardized murine pharmacokinetic (PK) model, we sought to determine the concordance of CNS penetration prediction by the CNS TAP Tool compared to the SwissADME BOILED-Egg computational model. Methods: Eleven drugs were chosen based on the most commonly altered and targeted pathways by our CNS tumor board. Mice were injected individually with the compounds of interest and sacrificed at four different time points to quantify drug concentration via LC-MS in brain tissue and blood samples for PK analyses (1,2,4,7 hours). The percent brain penetration (AUCbrain/plasma) was compared to published human phase I PK data and pathway IC-50 to determine if agents were adequately CNS penetrant. These results were compared against the CNS TAP Tool and BOILED-Egg prediction of CNS penetrance. Results: All 11 drugs chosen (Table) demonstrated adequate CNS penetration, suggesting likely CNS efficacy. The CNS TAP Tool correctly predicted 10/11 agents (91% concordance), the lone exception being panobinostat. In contrast, the BOILED-Egg model only successfully predicted 3/11 agents (27%). When restricting the analysis to drugs with >50% CNS penetration (ponatinib, panobinostat, and ONC-201), the BOILED-Egg model successfully predicted CNS penetration of all agents. Conclusions: The clinician-curated CNS TAP Tool more accurately predicted CNS penetration of precision medicine therapies than the BOILED-Egg computational model, which performed best for drugs that achieve extremely high CNS penetration. The resulting PK and CNS penetration data for all agents was utilized to update and refine the CNS TAP tool for future patient use. [Table: see text]

Serial plasma and CSF cell-free tumor DNA (cf-tDNA) tracking in diffuse midline glioma patients undergoing treatment with ONC201

2012

Background: Diffuse midline glioma (DMG) with the H3K27M mutation is a lethal childhood brain cancer, with patients rarely surviving 2 years from diagnosis. There are few available means of monitoring the disease beyond serial MRI scans, making clinical decision making slow, difficult, and often reactive. Methods: We conducted a multi-site phase 1 trial of the imipridone ONC201 for children with H3K27M-mutant glioma (NCT03416530). Patients enrolled on Arm D of the trial (n=24) underwent serial lumbar puncture (baseline, 2 and 6 months) for cell-free tumor DNA (cf-tDNA) analysis at time of MRI. Additionally, patients on all arms of the trial at the University of Michigan underwent serial plasma collection. CSF collection was feasible in this cohort, with no procedural complications. We collected a total of 96 plasma samples and 53 CSF samples from 29 patients, including those with H3F3A (H3.3) (n=13), HIST13HB (H3.1) (n= 4), and unknown H3 status/not biopsied (n=12) [range of 0-8 CSF samples and 0-10 plasma samples]. We performed digital droplet polymerase chain reaction (ddPCR) analysis and/or amplicon-based electronic sequencing (Oxford Nanopore) of cf-tDNA samples and compared variant allele fraction (VAF) to radiographic change (maximal 2D tumor area on MRI). Results: Preliminary analysis of samples (n=58) demonstrates a correlation between changes in tumor size and H3K27M cf-tDNA VAF, when removing samples with concurrent bevacizumab. Analysis of remaining CSF and plasma samples is ongoing, including analysis of novel biomarkers of response. In multiple cases, early reduction in CSF cf-tDNA predicts long-term clinical response (>1 year) to ONC201 and does not increase in cases of later-defined pseudo-progression (radiation necrosis). For example, a now 9-year old patient with thalamic H3K27M-mutant DMG underwent treatment with ONC201 after initial radiation and developed an increase in tumor size at 4 months post-radiation (124% baseline) of unclear etiology at the time. Meanwhile, her ddPCR declined from baseline 6.76% VAF to <1%, which has persisted, with now near complete response (85% tumor reduction) at 30 months on treatment from diagnosis. Conclusions: In summary, we present the feasibility and utility of serial CSF/plasma monitoring of a promising experimental therapy for DMG.

Targeted agents recommended by the CNS TAP tool compared to those selected by a tumor board in a molecularly-driven clinical trial in children and young adults with DIPG

2048

Background: Genetic sequencing of diffuse intrinsic pontine glioma (DIPG) and diffuse midline glioma (DMG) biopsy specimens has revealed genomic heterogeneity, fueling an interest in individualized, targeted treatment options. The Pacific Pediatric Neuro-Oncology Consortium recently completed a feasibility study PNOC003: Molecular Profiling for Individualized Treatment Plan for DIPG (NCT02274987), in which a multidisciplinary tumor board recommended targeted agents based on the molecular and genetic profiling of each patient’s tumor. Separately, our group developed a numeric scoring tool of targeted anticancer agents, the Central Nervous System Targeted Agent Prediction (CNS TAP) tool, which combines pre-clinical, clinical, and CNS penetration data with patient-specific genomic information to generate a numeric score for each agent to objectively evaluate these targeted therapies for use in patients with CNS tumors. We hypothesized that highly-scored agents within the CNS-TAP tool would overlap, at least in part, with the agents recommended by the molecular tumor board in PNOC003. Methods: For each study participant (n=28), a retrospective analysis was completed, utilizing the genomic report to identify actionable genetic alterations and to input patient-specific data into CNS TAP to identify the highest scoring agents. We compared high-scoring agents within the CNS TAP tool with recommendations from the PNOC003 tumor board for each of the enrolled 28 patients. Results: Overall, 93% (26/28) of patients had at least one agent recommended by both the tumor board and CNS TAP. Additionally, 39% (37/95) of all agents recommended by the tumor board were also selected by CNS TAP, with additional analysis ongoing. Conclusions: There was significant overlap between the highest-scoring and selected agents via CNS TAP compared with those chose by the molecular tumor board. Through this work, we also identified factors that likely contributed to the discordance in choice of targeted therapies. Without clinician input, the CNS TAP tool is unable to account for drug-drug interactions, includes only designated anticancer agents, and cannot easily be updated in real time, requiring extensive manual literature review for each included agent. However, CNS TAP provides an objective evaluation of targeted therapies, in contrast to inherently subjective recommendations of a tumor board. Given the discordance identified between these methods and the strengths of each, a prospective study incorporating both CNS TAP and a molecular tumor board for targeted therapy selection in patients with high grade glioma is warranted.

Clinical experience of ONC201 in patients with recurrent H3 K27M-mutant spinal cord glioma

2563

Background: High-grade gliomas of the spinal cord are a rare and understudied entity, representing < 5% of all spinal cord tumors. Reported median survival times range from 10-16 months. Up to 53% of tumors harbor the H3 K27M mutation, which is associated with an unfavorable prognosis. Postsurgical treatment often includes radiation ± temozolomide, although the role of chemotherapy has not been conclusively established. At recurrence, there are no effective therapies and most clinical studies exclude patients with spinal cord tumors. We report our clinical experience with ONC201, a small molecule DRD2 antagonist and caseinolytic protease P agonist, in patients with recurrent H3 K27M-mutant diffuse gliomas of the spinal cord (scDG). Methods: Adults and children with recurrent H3 K27M-mutant scDG received ONC201 in two Phase II clinical trials enrolling adult recurrent H3 K27M-mutant glioma patients (NCT02525692; NCT03295396) and in one Phase I clinical trial enrolling pediatric patients (NCT03416530). Adult patients received ONC201 at the RP2D dose of 625 mg weekly and pediatric patients received the RP2D of 625 mg weekly, scaled by body weight. All patients began ONC201 as a single agent until disease progression. Five patients continued ONC201 combined with bevacizumab beyond progression. Results: As of January 15, 2020, 12 evaluable patients (adult n = 8, pediatric n = 4) received ONC201. The median age was 20.9 (range: 7-72) years. The median follow-up time for the single agent ONC201 group was 5.4 (range 1.3-9.7) months while that of the combination group is 7.4 (range 6.2-25.1) months. The median number of ONC201 doses was 10 (range: 5-39) for the ONC201 single agent group and 34 (range: 21-100) for the combination group. Five of 7 patients remain alive in the ONC201 single agent group while 3 of 5 patients remain alive in the combination group. Three patients in the ONC201 single agent group and 2 patients in the combination group continue on treatment. There were no drug-related toxicities requiring dose reduction or discontinuation. Conclusions: Treatment with ONC201 alone or combined with bevacizumab is well tolerated in patients with recurrent H3 K27M-mutant scDG and a subset of patients experiences prolonged survival that exceeds historical outcomes. Clinical trial information: NCT02525692; NCT03295396; NCT03416530 .

ONC201 in previously irradiated pediatric H3 K27M-mutant glioma or newly diagnosed DIPG

3619

Background: ONC201 is a first-in-class DRD2 antagonist and ClpP agonist that has demonstrated promising activity in high-grade glioma preclinical models and radiographic regressions with single agent ONC201 in recurrent H3 K27M-mutant glioma patients . The recommended phase 2 dose (RP2D) of 625mg ONC201 orally once a week has been established in adult patients as well tolerated and biologically active. ONC201 efficacy has been shown in high-grade glioma preclinical models and radiographic regressions with single agent ONC201 have been reported in adult recurrent H3 K27M-mutant glioma patients. We report results from the first Phase I pediatric clinical trial of ONC201. Methods: This open-label, multi-center trial for pediatric H3 K27M-mutant glioma or non-biopsied DIPG employed a 3+3 dose-escalation and dose-expansion design with 6 arms. Arms A and E, which have completed accrual, determined the RP2D of ONC201 using oral capsule and liquid formulations in post-radiation pediatric H3 K27M-mutant glioma patients ONC201, respectively. Arm B aims to determine the RP2D for ONC201 in combination with radiotherapy in patients with newly diagnosed DIPG. Arms C and D aim to measure intratumoral ONC201 concentrations in midline glioma patients and the impact of ONC201 on H3 K27M DNA levels in CSF, respectively. Arm F was recently opened to study ONC201 as a single agent in patients with progressive H3 K27M-mutant tumors (excluding DIPG and spinal cord tumors) following radiotherapy. After determining the RP2D, a dose-expansion cohort will evaluate the safety, radiographic response, and activity of ONC201. Results: An RP2D of weekly 625mg ONC201 scaled by body weight as a capsule or in liquid formulation was established in the primary endpoints of arms A, B and E alone or in combination with radiation, without incidence of dose-limiting toxicity (DLT). Pharmacokinetic profiles were similar to those observed in adults (T1/2: 8.4h; Tmax: 2.1h; Cmax: 2.3ug/mL; AUC0-tlast: 16.4ug/mL), with similar exposure across body weights. Conclusions: ONC201 was well tolerated without DLTs at the same adult RP2D scaled by body weight as monotherapy or in combination with radiotherapy in pediatric H3 K27M-mutant glioma patients. Further investigation of ONC201 to treat H3 K27M-mutant glioma and DIPG is warranted. Clinical trial information: NCT03416530 .

Clinical efficacy of ONC201 in thalamic H3 K27M-mutant glioma

3617

Background: Diffuse midline gliomas, H3 K27M-mutant are associated with a poor prognosis compared to H3 wild-type gliomas and have no effective therapy following first-line radiation. ONC201 is a bitopic DRD2 antagonist and allosteric ClpP agonist that has shown encouraging single agent efficacy in recurrent H3 K27M-mutant gliomas located in various midline structures of the brain. In addition to tumor and immune cells, the pharmacodynamics of ONC201 extend to stromal cells that can mediate a bystander antitumor response in preclinical models. Given this observation and that the thalamus has the highest extrastriatal expression of DRD2, we report the clinical experience of ONC201 in a subgroup of H3 K27M-mutant glioma patients with primary tumors located in the thalamus. Methods: We analyzed 29 thalamic H3 K27M-mutant glioma patients treated with ONC201 in clinical trials enrolled as of 5/22/19. Nineteen enrolled with recurrent disease whereas 10 enrolled following radiation prior to recurrence. Twelve patients enrolled on NCT03295396, 10 NCT03416530, 4 NCT02525692, and 3 expanded access. Median age was 22 years old (range: 5-70) and baseline KPS was 80 (range: 60-90). Median time from radiation to start of ONC201 was 1.8 months (range: 0.2-8.7) for non-recurrent patients and 7.2 months (range: 1.4-102.0) for recurrent patients. Results: As of 12/18/2019, PFS6 and OS12 measured relative to initiation of ONC201 are 26.3% and 36.8%, respectively, in the recurrent group. For patients initiating ONC201 post-radiation prior to recurrence, median PFS or OS have not been reached with a median follow up of 21.9 months (8.6-26.6) from diagnosis, which surpass historical OS of 13.5 months. Best response for evaluable recurrent patients by RANO: 1 CR, 3 PR, 4 SD, 8 PD, 3 not reported; for non-recurrent patients: 2 PR, 4 SD, 1 PD, 3 not reported. Median duration of response for recurrent patients is 14.0 months (2.0-33.1). ONC201 was well tolerated and no dose-limiting toxicities or treatment discontinuations due to toxicity occurred. Furthermore, H3 K27M cell-free tumor DNA in plasma and CSF correlated with MRI response. Conclusions: In summary, single agent ONC201 administered at recurrence or following radiation, demonstrates promising clinical efficacy in thalamic H3 K27M-mutant glioma patients. Investigations are ongoing to assess whether micro-environmental DRD2 expression correlates with responses of thalamic H3 K27M-mutant glioma to ONC201. Clinical trial information: NCT03295396, NCT03416530, NCT02525692 .

The effect of everolimus on CNS penetration and efficacy of dasatinib in the treatment of PDGFRA-driven glioma

e13508

Background: Pediatric and adult high-grade glioma (HGG) frequently harbor PDGFRA alterations. The CNS penetration of PDGFRA inhibitors, such as dasatinib, is limited by the tumor-efflux protein P-glycoprotein (P-gp). We hypothesized that co-treatment with everolimus, which has been shown to block P-gp, will increase CNS penetration and efficacy of dasatinib in in vitro and in vivo models as well as in human PDGFRA-driven glioma. Methods: Tumors were generated in mice using an intra-uterine electroporation (IUE) model [introduction of TP53, PDGFRA and H3K27M mutations in pre-natal cortex]. Dose response, synergism studies, P-GP inhibition and pharmacodynamics/pharmacokinetic studies were then performed on in vitro and in vivo models employing this IUE system. A phase 2 trial employing dasatinib and everolimus was established for children with HGG and diffuse intrinsic pontine glioma (DIPG) that contain PDGFRA alterations (NCT03352427). Paired CSF/plasma samples (before and after addition of everolimus) were collected from enrolled patients. Results: Dasatinib effectively treated mouse HGG cells with an IC50 of 100 nM. Dose-dependent reduction in PDGFRA and pPDGFRA was found. P-gp inhibitor assay confirmed that everolimus strongly blocks P-gp activity at 1 uM (p = 0.0028 vs untreated). Mice treated with dasatinib and everolimus had extended survival as compared to control. Two-hour exposure to everolimus resulted in sub-IC50 dasatinib concentration in cortex (23 nM) and tumor (65 nM). 24-hour exposure to everolimus resulted in greater cortex (235 nM) and tumor (509 nM) concentrations. Two trial patients, recurrent HGG ( PDGFRA-amplified) and recurrent DIPG ( PDGFRA D842V) respectively, survived 6 months and 9 months (ongoing) after progression, which compares very favorably to historical controls. A paired CSF sample from the PDGFRA-amplified patient showed a 50% increase in CSF dasatinib level after addition of everolimus. Conclusions: Dasatinib treatment of PDGFRA-driven HGG is improved with everolimus blockade of P-gp and represents a novel route for improving CNS penetration and efficacy of therapies for HGG. Clinical trial information: NCT03352427.

ONC201 in previously-irradiated pediatric H3 K27M-mutant glioma

10046

Background: ONC201 is the first DRD2 antagonist for clinical oncology. The recommended phase 2 dose (RP2D) of 625mg ONC201 orally once a week has been established in adult patients. ONC201 efficacy has been shown in high-grade glioma preclinical models and radiographic regressions with single agent ONC201 have been reported in adult recurrent H3 K27M-mutant glioma patients. We report results from the first Phase I pediatric clinical trial of ONC201. Methods: This multicenter, open-label, dose-escalation and dose-expansion clinical trial (NCT03416530) determined the RP2D of ONC201 in pediatric H3 K27M-mutant glioma patients as a single agent. ONC201 was orally administered once a week and scaled by body weight. Dose escalation was performed by a 3 + 3 design beginning with one 125mg capsule less than the adult RP2D equivalent. Three patients were treated at the starting dose and 19 were treated at the adult RP2D equivalent. Results: The primary endpoint was achieved by establishing the safety of the adult RP2D scaled by body weight to pediatric patients. Twenty-two patients with a median age of 9 (range 3-18) years old who received at least prior radiation have been treated with ONC201: 15 with diffuse intrinsic pontine glioma (DIPG) (4 recurrent; 11 not recurrent) and 7 with non-DIPG H3 K27M-mutant glioma (all not recurrent). As of February 5, 2019, patients have received a median of 18 ONC201 doses (range 3-41) without instance of dose-limiting toxicity. Pharmacokinetic profiles were comparable to those observed in adults (Cmax ~2.1ug/mL; AUC ~2.3hr*ug/mL) and exposure was similar across body weights. Nine of 22 patients remain on therapy, 13 have discontinued due to progression, and 4 off-study patients are alive with a median follow up of 5.8 months. Five of the 11 (45%) DIPG patients who initiated ONC201 following radiation, but prior to recurrence, remain on therapy (median 7.4 months; range 4.4-9.6): median PFS is 4.4 months from initiation of ONC201 and 9.7 months from diagnosis; 7 of 11 (64%) patients are alive with median follow up of 11.8 months from diagnosis. Conclusions: ONC201 was well tolerated and achieved therapeutic exposure in pediatric H3 K27M-mutant glioma patients at the adult RP2D scaled by body weight. Further investigation of first-line ONC201 to treat H3 K27M-mutant glioma and/or DIPG is ongoing. Clinical trial information: NCT03416530.