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highlights:2025:brainvr [2026/02/10 08:23] Ronell Sicathighlights:2025:brainvr [2026/02/10 11:00] (current) Ronell Sicat
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-{{wiki:highlights:2025:brainem.png?400|}}+{{:wiki:highlights:2025:spatial_marifer4.png?400|}}
  
 <WRAP center round box 100%> {{:favicon.ico?nolink&0x30}} <fs:26px>** KVL Staff on Project**</fs> <WRAP center round box 100%> {{:favicon.ico?nolink&0x30}} <fs:26px>** KVL Staff on Project**</fs>
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 During November and December 2025, Dr. María Fernanda Veloz Castillo presented her PhD research at two international conferences: the [[https://www.sfn.org/meetings/neuroscience-2025|Society for Neuroscience Annual Meeting]] in San Diego (November 15-19) and the [[https://natureconferences.streamgo.live/brain-health-energy|Nature Conference on Brain Energy Metabolism in Health and Disease]] (December 3-5). At both events, the work presented highlighted the results of her doctoral research focused on glycogen metabolism during learning, with particular emphasis on the structural insights gained through advanced imaging using volume electron microscopy (vEM) and 3D reconstruction of key cellular compartments. During November and December 2025, Dr. María Fernanda Veloz Castillo presented her PhD research at two international conferences: the [[https://www.sfn.org/meetings/neuroscience-2025|Society for Neuroscience Annual Meeting]] in San Diego (November 15-19) and the [[https://natureconferences.streamgo.live/brain-health-energy|Nature Conference on Brain Energy Metabolism in Health and Disease]] (December 3-5). At both events, the work presented highlighted the results of her doctoral research focused on glycogen metabolism during learning, with particular emphasis on the structural insights gained through advanced imaging using volume electron microscopy (vEM) and 3D reconstruction of key cellular compartments.
  
-A key component of this work was developed in close collaboration between the Laboratory of Prof. Pierre Magistretti and Dr. Ronell Sicat from the KAUST Visualization Core Lab, which explores how immersive visualization could enhance not only data analysis, but also scientific communication.+A key component of this work was developed in close collaboration between the Laboratory of Prof. Pierre Magistretti and Dr. Ronell Sicat from the KAUST Visualization Core Lab, which explored how immersive visualization could enhance not only data analysis, but also scientific communication.
  
 ===== Turning Poster Presentations into Immersive Journeys ===== ===== Turning Poster Presentations into Immersive Journeys =====
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 The datasets presented at both conferences consisted of large vEM image stacks of hippocampal brain tissue, comparing focused-beam microwave fixation with chemical fixation. Key structures from these datasets were reconstructed in 3D to better capture the spatial organization relevant to glycogen metabolism in learning-related processes. The datasets presented at both conferences consisted of large vEM image stacks of hippocampal brain tissue, comparing focused-beam microwave fixation with chemical fixation. Key structures from these datasets were reconstructed in 3D to better capture the spatial organization relevant to glycogen metabolism in learning-related processes.
  
-To allow conference attendees to truly appreciate the scale, complexity, and spatial relationships within these datasets, we moved beyond a traditional poster-only format. Instead, the 3D reconstructions were placed inside a metaverse environment, where participants could explore them interactively using a Meta Quest 3 virtual reality (VR) headset. The virtual room also included the poster itself, allowing attendees to move freely between reading the content and figures, and directly engaging with the data in three dimensions.+To allow conference attendees to truly appreciate the scale, complexity, and spatial relationships within these datasets, the team went beyond a traditional poster-only format. Instead, the 3D reconstructions were placed inside a metaverse environment, where participants could explore them interactively using a Meta Quest 3 virtual reality (VR) headset. The virtual room also included the poster itself, allowing attendees to move freely between reading the content and figures, and directly engaging with the data in three dimensions.
  
 This immersive setup had a clear impact on how people interacted with the work. Attendees were noticeably more inclined to stop at the poster, ask questions, and spend time exploring the data. The ability to navigate the 3D reconstructions made it easier to explain why spatial context is critical for interpreting biological processes such as glycogen distribution and metabolism in the hippocampus. This immersive setup had a clear impact on how people interacted with the work. Attendees were noticeably more inclined to stop at the poster, ask questions, and spend time exploring the data. The ability to navigate the 3D reconstructions made it easier to explain why spatial context is critical for interpreting biological processes such as glycogen distribution and metabolism in the hippocampus.
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-{{ :wiki:highlights:2025:brainem_poster_preview.png?600 | Poster preview.}}+{{ :wiki:highlights:2025:poster_marifer2.png?700 | Poster preview.}}
  
 [[https://download.vis.kaust.edu.sa/pub/misc/poster_brain_em.pdf|Click here to download full pdf version of poster.]] [[https://download.vis.kaust.edu.sa/pub/misc/poster_brain_em.pdf|Click here to download full pdf version of poster.]]