An EWSR1-EZHIP fusion in a cerebral hemisphere astroblastoma.

Astroblastomas are considered extremely rare tumors and have not been formally graded. While gene mutations are used to diagnose these tumors, further research is needed for proper diagnosis and classification. This report presents a case of astroblastoma in a 44-year-old woman. A tumor was found to have histology consistent with astroblastoma, with no MN1 gene changes. Several mutations were present, and fusion of the EWSR1 and EZHIP genes was noted, which has never been reported before in the literature. Fusions of the EWSR1 gene could be characteristics of astroblastomas, in addition to MN1 alterations, and identification of these mutations could help in the diagnosis of these rare tumors.

Recurrent high-grade astroblastoma with MN1-BEND2 fusion in spinal cord and literature review.

Astroblastoma is an uncommon tumor of the central nervous system. It is variable in morphology, but the astroblastic pseudorosettes and vascular hyalinization are the most important features. Most astroblastomas occur in the cerebral hemisphere. We report a recurrent high-grade astroblastoma with MN1-BEND2 fusion in the spinal cord. Two lesions were found in the T5-7 level and T12-L1 level, and they were well defined in images. Rhabdoid and signet-ring-like cells were observed. It may be classified as a high-grade tumor due to cellularity, high mitotic count, and pleomorphism. The tumor cells were diffusely positive for GFAP, Olig-2, and S-100 protein. We found the MN1 arrangement and the loss of chromosome 1p by FISH, and further validated the BEN domain containing 2 genes (BEND2), which is the fusion partner of meningioma 1 gene (MN1), by next-generation sequencing (NGS) and Sanger sequencing. The MN1 mutation is crucial in the diagnosis and prognosis of rare astroblastoma. The spinal cord astroblastoma may have a high recurrence rate because of the residual lesion at the unique location and higher grade; the connection with the gene mutation is unclear. Regular follow-up is necessary. Further study and more cases are needed to establish evidence for diagnosis, prognosis, and treatment of astroblastoma with molecular characteristics.

Graphene-enhanced metal oxide gas sensors at room temperature: a review.

Owing to the excellent sensitivity to gases, metal-oxide semiconductors (MOS) are widely used as materials for gas sensing. Usually, MOS gas sensors have some common shortages, such as relatively poor selectivity and high operating temperature. Graphene has drawn much attention as a gas sensing material in recent years because it can even work at room temperature, which reduces power consumption. However, the low sensitivity and long recovery time of the graphene-based sensors limit its further development. The combination of metal-oxide semiconductors and graphene may significantly improve the sensing performance, especially the selectivity and response/recovery rate at room temperature. In this review, we have summarized the latest progress of graphene/metal-oxide gas sensors for the detection of NO2, NH3, CO and some volatile organic compounds (VOCs) at room temperature. Meanwhile, the sensing performance and sensing mechanism of the sensors are discussed. The improved experimental schemes are raised and the critical research directions of graphene/metal-oxide sensors in the future are proposed.