RESUMO
PURPOSE: Although social media platforms have made information about autism more accessible to the general public, concerns have been raised about the unfiltered nature of the content they host. In the current study, we examined the reach and accuracy of videos providing informational content about autism on TikTok, a popular social media platform. METHODS: We examined engagement indicators (including views and "likes") for the TikTok videos associated with the #Autism hashtag. Two coders independently fact-checked informational content of the most viewed videos from the #Autism hashtag videos and coded it as either accurate, inaccurate or 'overgeneralization' based on the consistency of the information in the videos with current knowledge on autism. RESULTS: Videos associated with the "#Autism" hashtag accrued 11.5 billion views collectively. An examination of the top 133 videos providing informational content on autism, which totaled 198.7 million views and 25.2 million likes, showed that 27% of the videos were classified as accurate, while 41% were classified as inaccurate and 32% as overgeneralized. There were no significant differences in engagement between accurate and inaccurate/overgeneralized videos. Videos created by healthcare professionals were more likely to include accurate information. CONCLUSION: The informational content about autism made available on TikTok reaches a wide number of people. Most of the information provided, however, appears to be misaligned with current knowledge. It is important for healthcare providers and other professionals to be aware of the autism-related content being shared on TikTok so that they can better engage with the large community of TikTok users.
RESUMO
Mechanochemistry enables transformations of highly insoluble materials such as uranium dioxide or the mineral studtite [(UO2)(O2)(H2O)2]·(H2O)2 into uranyl triperoxide compounds that can subsequently assemble into hydroxide-bridged uranyl peroxide dimers in the presence of lithium hydroxide. Dissolution of these solids in water yields uranyl peroxide nanoclusters including U24, Li24[(UO2)(O2)(OH)]24. Insoluble uranium solids can transform into highly soluble uranyl peroxide phases in the solid state with miniscule quantities of water. Such reactions are potentially applicable to uranium processing in the front and back end of the nuclear fuel cycle.