RESUMEN
Many metal-organic frameworks (MOFs) suffer from stability issues as they can be easily amorphized from various external stimuli. In particular, it is common to observe structural collapse during the activation process of removing the synthesis solvent. In this study, we conduct high-throughput computational analysis that focuses on the activation status of MOFs that possess copper paddlewheel metal nodes. From the analysis, various mechanical properties (e.g., bulk, Young's, and shear moduli) were found to be good predictors for collapse. Furthermore, we have identified anomaly MOFs with good mechanical stability that were previously reported to collapse. Accordingly, the activation process was reattempted with improved techniques, and one of these MOFs was successfully activated.
RESUMEN
Schizophrenia has been conceptualized to be a neurodevelopmental disorder. Neuroimaging evidence was generally findings of volumetric reductions in various brain structures. The shape analysis of the insula can uncover unique structural deformity in the neurodevelopmental disorder, which cannot be revealed from a simple volume measurement. The objective of this study was to demonstrate a subtle change of the insula in schizophrenia using our special shape analysis technique. Subjects were 23 patients with schizophrenia and 23 normal healthy subjects. A landmark-based structural and surface shape analysis of the insula was performed using high-spatial resolution magnetic resonance imaging. A characteristic finding was that the frontotemporal sides of the right insula were deformed in the patients with schizophrenia compared with normal controls. This deformation can be associated with abnormal development of the frontal and temporal lobes in schizophrenia.