TY - GEN
T1 - Visual analysis of glycogen derived lactate absorption in dense and sparse surface reconstructions of rodent brain structures
AU - Calì, C.
AU - Agus, M.
AU - Gagnon, N.
AU - Hadwiger, M.
AU - Magistretti, P. J.
N1 - Funding Information:
Acknowledgements. We thank Kalpana Kare and Daniya Boges for the technical support for the 3D reconstruction pipelines and coding; the KVL team for the support in the use of CAVE and for providing computing clusters to process the image stacks for 3D reconstructions; Graham Knott and the BioEM Facility at EPFL (Lausanne, Switzerland), and Elena Vezzoli from University of Milano (Milano, Italy), for providing the EM stacks that we used for extracting the 3D models. This work was supported by the KAUST Grant KAUST-EPFL Alliance for Integrative Modeling of Brain Energy Metabolism to Pierre Magistretti and Henry Markram.
Funding Information:
We thank Kalpana Kare and Daniya Boges for the technical support for the 3D reconstruction pipelines and coding; the KVL team for the support in the use of CAVE and for providing computing clusters to process the image stacks for 3D reconstructions; Graham Knott and the BioEM Facility at EPFL (Lausanne, Switzerland), and Elena Vezzoli from University of Milano (Milano, Italy), for providing the EM stacks that we used for extracting the 3D models. This work was supported by the KAUST Grant KAUST-EPFL Alliance for Integrative Modeling of Brain Energy Metabolism to Pierre Magistretti and Henry Markram.
Publisher Copyright:
© 2017 The Author(s) Eurographics Proceedings © 2017 The Eurographics Association.
PY - 2020
Y1 - 2020
N2 - Astrocytes are the most abundant type of glial cells of the central nervous system; their involvement in brain functioning, from synaptic to network level, is to date a matter of intense research. A well-established function of astroglial cells, among others, is the metabolic support of neurons. Recently, it has been shown that during tasks like learning and long-term memory formation, synapses sustain their metabolic needs using lactate, a compound that astrocytes can synthesize from glycogen, a molecule that stores glucose, rather than glucose itself. Aforementioned role of astrocytes, as energy reservoir to neurons, is challenging the classic paradigms of neuro-energetic research. Understanding their morphology at nano-scale resolution is therefore a fundamental research challenge with enormous implications on many branches of neuroscience research, such as the study of neuro-degenerative and cognitive disorders. Here, we present an illustrative visualization technique customized for the analysis of the interaction of astrocytic glycogen on surrounding neurites in order to formulate hypotheses on the energy absorption mechanisms. The method integrates a high-resolution surface reconstruction of neurites and the energy sources in form of glycogen granules, and computes an absorption map according to a radiance transfer mechanism. The technique is built on top of a framework for processing and rendering triangulated surface models, and it is used for real-time 3D exploration and inspection of the neural structures paired with the energy sources. The resulting visual representation provides an immediate and comprehensible illustration of the areas in which the probability of lactate shuttling is higher. This method has been further employed for testing neuroenergetics hypotheses about the utilization of glycogen during synaptic development.
AB - Astrocytes are the most abundant type of glial cells of the central nervous system; their involvement in brain functioning, from synaptic to network level, is to date a matter of intense research. A well-established function of astroglial cells, among others, is the metabolic support of neurons. Recently, it has been shown that during tasks like learning and long-term memory formation, synapses sustain their metabolic needs using lactate, a compound that astrocytes can synthesize from glycogen, a molecule that stores glucose, rather than glucose itself. Aforementioned role of astrocytes, as energy reservoir to neurons, is challenging the classic paradigms of neuro-energetic research. Understanding their morphology at nano-scale resolution is therefore a fundamental research challenge with enormous implications on many branches of neuroscience research, such as the study of neuro-degenerative and cognitive disorders. Here, we present an illustrative visualization technique customized for the analysis of the interaction of astrocytic glycogen on surrounding neurites in order to formulate hypotheses on the energy absorption mechanisms. The method integrates a high-resolution surface reconstruction of neurites and the energy sources in form of glycogen granules, and computes an absorption map according to a radiance transfer mechanism. The technique is built on top of a framework for processing and rendering triangulated surface models, and it is used for real-time 3D exploration and inspection of the neural structures paired with the energy sources. The resulting visual representation provides an immediate and comprehensible illustration of the areas in which the probability of lactate shuttling is higher. This method has been further employed for testing neuroenergetics hypotheses about the utilization of glycogen during synaptic development.
UR - http://www.scopus.com/inward/record.url?scp=85063249810&partnerID=8YFLogxK
U2 - 10.2312/stag.20171224
DO - 10.2312/stag.20171224
M3 - Conference contribution
AN - SCOPUS:85063249810
T3 - Italian Chapter Conference 2017 - Smart Tools and Apps in computer Graphics, STAG 2017
SP - 31
EP - 38
BT - Italian Chapter Conference 2017 - Smart Tools and Apps in computer Graphics, STAG 2017
A2 - Giachetti, Andrea
A2 - Pingi, Paolo
A2 - Stanco, Filippo
PB - Eurographics Association
T2 - 2017 Italian Chapter Conference - Smart Tools and Apps in Computer Graphics, STAG 2017
Y2 - 11 September 2017 through 12 September 2017
ER -