Xiaoyang Kang scite author profile

Graphical AbstractHighlights d Characterization of the mutational landscape of secondary glioblastoma d Clonal and subclonal METex14 promote glioma progression and mark worse prognosis d PLB-1001 is a highly selective, efficient, and BBB-permeable MET kinase inhibitor d PLB-1001 provides a safe and efficacious therapeutic approach for glioma treatment SUMMARY Low-grade gliomas almost invariably progress into secondary glioblastoma (sGBM) with limited therapeutic option and poorly understood mechanism. By studying the mutational landscape of 188 sGBMs, we find significant enrichment of TP53 mutations, somatic hypermutation, MET-exon-14-skipping (METex14), PTPRZ1-MET (ZM) fusions, and MET amplification. Strikingly, METex14 frequently co-occurs with ZM fusion and is present in $14% of cases with significantly worse prognosis. Subsequent studies show that METex14 promotes glioma progression by prolonging MET activity. Furthermore, we describe a MET kinase inhibitor, PLB-1001, that demonstrates remarkable potency in selectively inhibiting MET-altered tumor cells in preclinical models. Importantly, this compound also shows blood-brain barrier permeability and is subsequently applied in a phase I clinical trial that enrolls MET-altered chemo-resistant glioma patients. Encouragingly, PLB-1001 achieves partial response in at least two advanced sGBM patients with rarely significant side effects, underscoring the clinical potential for precisely treating gliomas using this therapy.

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Neuroprosthetic baroreflex controls haemodynamics after spinal cord injury

Squair

Gautier

Mahe

et al. 2021

Nature

117

123

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Graphene oxide doped conducting polymer nanocomposite film for electrode-tissue interface

et al. 2014

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Soft, Implantable Bioelectronic Interfaces for Translational Research

et al. 2020

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The convergence of materials science, electronics, and biology, namely bioelectronic interfaces, leads novel and precise communication with biological tissue, particularly with the nervous system. However, the translation of lab‐based innovation toward clinical use calls for further advances in materials, manufacturing and characterization paradigms, and design rules. Herein, a translational framework engineered to accelerate the deployment of microfabricated interfaces for translational research is proposed and applied to the soft neurotechnology called electronic dura mater, e‐dura. Anatomy, implant function, and surgical procedure guide the system design. A high‐yield, silicone‐on‐silicon wafer process is developed to ensure reproducible characteristics of the electrodes. A biomimetic multimodal platform that replicates surgical insertion in an anatomy‐based model applies physiological movement, emulates therapeutic use of the electrodes, and enables advanced validation and rapid optimization in vitro of the implants. Functionality of scaled e‐dura is confirmed in nonhuman primates, where epidural neuromodulation of the spinal cord activates selective groups of muscles in the upper limbs with unmet precision. Performance stability is controlled over 6 weeks in vivo. The synergistic steps of design, fabrication, and biomimetic in vitro validation and in vivo evaluation in translational animal models are of general applicability and answer needs in multiple bioelectronic designs and medical technologies.

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Xiaoyang Kang

Mutational Landscape of Secondary Glioblastoma Guides MET-Targeted Trial in Brain Tumor

Neuroprosthetic baroreflex controls haemodynamics after spinal cord injury

Graphene oxide doped conducting polymer nanocomposite film for electrode-tissue interface

Soft, Implantable Bioelectronic Interfaces for Translational Research

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