DIPG-54. UPDATED FINDINGS FROM THE PHASE IB STUDY OF UNESBULIN (PTC596) IN CHILDREN WITH NEWLY-DIAGNOSED DIFFUSE INTRINSIC PONTINE GLIOMA (DIPG) AND HIGH-GRADE GLIOMA (HGG): A REPORT FROM THE COLLABORATIVE NETWORK FOR NEURO-ONCOLOGY CLINICAL TRIALS (CONNECT)

BMI-1 represents a potential therapeutic target in pediatric HGG given its role in self-renewal and DNA-damage signaling, high expression levels in these tumors, and resultant proliferation blockade, mitotic abnormalities, and radiosensitization when modulated by unesebulin, a microtubule polymerization inhibitor. This phase Ib study sought to determine the recommended phase 2 dose (RP2D) and pharmacokinetic (PK) profiles of unesbulin administered concurrently with radiotherapy and as maintenance therapy in children with newly-diagnosed DIPG or HGG, as well as assess intratumoral PKs and target inhibition within a surgical cohort. As previously reported, the established RP2D from the dose-finding cohort (parts A [capsule] and C [tablet]), consisting of 27 patients (median age: 9 years; 18 with DIPG, 9 with HGG) is 200mg/m(2) twice weekly. Eleven additional patients (5 with DIPG, 6 with HGG) have been enrolled in an expansion cohort (part D [tablet]), with no dose-modifying toxicities to date. Among 38 total patients, most common drug-related grade 3/4 adverse effects observed are neutropenia (49%), leukopenia (31%), and elevated ALT (18%). Pharmacokinetic profiles are comparable between capsule and tablet formulations, and corroborate adult data. Genomics correlatives are underway on 13 biopsy and 5 autopsy specimens (2 paired samples). Five patients (median age: 5 years; 4 with DIPG, 1 with HGG) have enrolled in the surgical cohort (part B [tablet]) at the RP2D. PK analyses performed on the first three samples confirm intratumoral unesbulin exposure. In summary, the RP2D of unesbulin at 200mg/m(2) twice weekly concurrent with and post-radiotherapy is feasible and well-tolerated, with evidence of blood-brain barrier and tumor penetrance. Survival outcomes as well as ongoing analyses of intratumoral BMI-1 pathway inhibition in surgical cohort samples, plus comprehensive molecular profiling (focusing on BMI-1 and cell cycle signaling) of biopsy and autopsy specimens from the entire cohort, will be shared at time of presentation.