Cleft Lip and Palate Research in the United Kingdom: Advances in Clinical Psychological Knowledge and Future Directions.

In 2012, the James Lind Alliance (JLA) worked with individuals with cleft lip and/or palate (CL/P), their families and clinicians to identify priority areas for future research. This article reviews progress conducted in the United Kingdom in the 3 JLA priorities most closely related to Clinical Psychology. It then builds upon the original priorities to identify 4 future directions, based on contemporary literature and in-depth discussions between clinical and research experts.

Synthetic Aspects and Characterization Needs in MOF Chemistry - from Discovery to Applications.

Even if MOFs are recently developed for large-scale applications, the road to applications of MOFs is long and rocky. This requires to overcome challenges associated with phase discovery, synthesis optimization, basic and advanced characterization, and computational studies. Lab-scale results need to be transferred to large-scale processes, which is often not trivial, and life-cycle analyses and techno-economic analyses need to be performed to realistically assess their potential for industrial relevance.

Nanoscale Connectomics Annotation Standards Framework.

The promise of large-scale, high-resolution datasets from Electron Microscopy (EM) and X-ray Microtomography (XRM) lies in their ability to reveal neural structures and synaptic connectivity, which is critical for understanding the brain. Effectively managing these complex and rapidly increasing datasets will enable new scientific insights, facilitate querying, and support secondary use across the neuroscience community. However, without effective neurodata standards that permit use of these data across multiple systems and workflows, these valuable and costly datasets risk being underutilized especially as they surpass petascale levels.

Unlocking the Chemical and Structural Complexity of Aluminum Hydroxy Acetates: from Commodity Chemicals to Porous Materials.

Aluminum acetates have been in use for more than a century, but despite their widespread commercial applications, essential scientific knowledge of their synthesis-structure-property relationships is lacking. High-throughput screening, followed by fine tuning and extensive optimization of reaction conditions using Al, OH and CHCOO ions, has unraveled their complex synthetic chemistry, yielding for the first time the four phase pure products Al(OH)(OCCH) ⋅ x HO (x=0, 2) (1A and CAU-65, 1B), AlO(HOCCH)(OCCH) (2), and the porous aluminum salt [Al(OH)(CHCOO)](OH) (CAU-55-OH, 3). Structure determination by electron and X-ray diffraction was carried out and the data suggested porosity for 1B and 3, which was confirmed by physisorption experiments.