Use of hyperbaric oxygen therapy in pediatric neuro-oncology: a single institutional experience.

INTRODUCTION: Hyperbaric oxygen therapy (HBOT) has been utilized as adjunctive treatment of CNS tumors and for radiation necrosis (RN) with reported success. The safety and efficacy in pediatric patients is less understood. METHODS: Seven patients (ages 10-23 years, six females) were treated with HBOT (3-60 sessions) for either RN (n = 5) or tumor-associated edema (n = 2). Tumor diagnosis included low-grade glioma (n = 4, two with neurofibromatosis type 1), meningioma (n = 1), medulloblastoma (n = 1) and secondary high grade glioma (n = 1). Prior therapies included: surgery (n = 4), chemotherapy (n = 4) and radiation (N = 5: four focal, one craniospinal). Three underwent biopsy: one confirming RN, one high-grade glioma, and one low-grade glioma. Patients were assessed for clinical and radiographic changes post HBOT. RESULTS: Median time to clinical and radiographic presentation was 8.5 months (range 6 months-11 years) in those who had prior radiation. Clinical improvement after HBOT (median: 40 sessions) was observed in four of seven patients. Symptoms were stable in two and worsened in one patient. Radiographic improvement was seen in four patients; three had radiographic disease progression. In the subgroup treated for presumed and biopsy-confirmed RN (n = 5), four of five (80%) had clinical and radiographic improvement. There were no long-term adverse events due to HBOT. CONCLUSIONS: HBOT is safe and well-tolerated in pediatric and young adult patients with CNS tumors. Clinical and radiographic improvements were observed in over half of patients. Clinical trials are needed to establish safety and efficacy of HBOT as adjunct therapy in pediatric CNS tumors.

Nivolumab in the Treatment of Recurrent or Refractory Pediatric Brain Tumors: A Single Institutional Experience.

Successful use of immune checkpoint inhibitors in a variety of cancers has generated interest in using this approach in pediatric brain tumors. We performed a retrospective review of 10 consecutive children (6 boys, 4 girls; ages, 2 to 17 y), with recurrent or refractory pediatric brain tumors (5 high-grade glioma, 1 low-grade glioma, pineoblastoma, medulloblastoma, ependymoma, and CNS embryonal tumor, NOS) treated at Rady Children's Hospital San Diego from 2015 to 2017 with the immune checkpoint inhibitor nivolumab (3 mg/kg every 2 wk). Eight of 10 patients received prior chemotherapy and 9 radiation therapy. Nine patients had radiographic disease progression (median, 2.5 doses). Median time to progression was 5.5 weeks (1.6 to 24 wk). Three patients (2 with high-grade glioma, 1 with CNS embryonal tumor NOS) showed a partial response to treatment at the primary tumor site and 2 of 3 had progression of metastatic disease. Grade 2 toxicities were observed without dose limiting side effects. Tumor mutation burden (TMB) was low to intermediate (median, 1.3; range, 0 to 6.3). Median survival for PD-L1 positive patients was 13.7 weeks versus 4.2 weeks for PD-L1 negative patients (ρ=0.08) nivolumab was well tolerated in our series of pediatric recurrent brain tumors with some transient partial responses in patients with positive PD-L1 expression and higher TMB. Our findings suggest that the use of immune checkpoint inhibitors in pediatric brain tumor patients should be limited to those with elevated PD-L1 expression and TMB.

Single-agent bevacizumab in the treatment of recurrent or refractory pediatric low-grade glioma: A single institutional experience.

INTRODUCTION: Bevacizumab-based therapy has been demonstrated to be effective in the treatment of refractory or recurrent pediatric low-grade glioma (LGG); however its efficacy as a single agent is less understood. METHODS: We report our experience with single-agent bevacizumab for the treatment of recurrent or refractory LGG treated with either standard 2 week dosing (10 mg/kg/dose every 2 weeks) or with a standard 2 week dosing followed by an increased interval dosing (10 mg/kg/dose every 4 weeks). RESULTS: From 2012 to 2017, 15 patients (five males and 10 females) with recurrent/refractory LGG (nine suprasellar, three thalamic, two brainstem, and one intramedullary spinal cord) were treated with a total of 156 doses of bevacizumab (115 every 2 week dosing, 41 every 4 week dosing, median 10 doses). Patients were refractory to a median of one nonsurgical therapy (range 0-3) prior to treatment with bevacizumab. Twelve of 15 demonstrated radiographic response (three complete, nine partial, and three stable disease). Significant clinical responses including improved visual fields (four), cranial neuropathy (three3), strength (seven), and gait (two) were observed. Bevacizumab was discontinued in 12 patients (resolution, one; disease stability, seven; progression, two; toxicity, one; and other, one) and three patients continue to receive monthly bevacizumab. Eleven patients eventually had radiographic progression (median 5 months, range 0.5-31) without clinical progression, and four of five receiving bevacizumab rechallenge had lpartial response. CONCLUSION: Single-agent bevacizumab is efficacious in the management of recurrent or refractory pediatric LGG with radiographic and clinical responses similar to those reported for bevacizumab-based therapies.