Your search keyword '"Malika S. Datta"' showing total 4 results

1. Light sheet theta microscopy for rapid high-resolution imaging of large biological samples

Author

Bianca Migliori, Malika S. Datta, Christophe Dupre, Mehmet C. Apak, Shoh Asano, Ruixuan Gao, Edward S. Boyden, Ola Hermanson, Rafael Yuste, and Raju Tomer

Subjects

Light sheet microscopy, Whole brain imaging, Quantitative imaging, Hydra, Calcium imaging, Tissue clearing, Biology (General), QH301-705.5

Abstract

Abstract Background Advances in tissue clearing and molecular labeling methods are enabling unprecedented optical access to large intact biological systems. These developments fuel the need for high-speed microscopy approaches to image large samples quantitatively and at high resolution. While light sheet microscopy (LSM), with its high planar imaging speed and low photo-bleaching, can be effective, scaling up to larger imaging volumes has been hindered by the use of orthogonal light sheet illumination. Results To address this fundamental limitation, we have developed light sheet theta microscopy (LSTM), which uniformly illuminates samples from the same side as the detection objective, thereby eliminating limits on lateral dimensions without sacrificing the imaging resolution, depth, and speed. We present a detailed characterization of LSTM, and demonstrate its complementary advantages over LSM for rapid high-resolution quantitative imaging of large intact samples with high uniform quality. Conclusions The reported LSTM approach is a significant step for the rapid high-resolution quantitative mapping of the structure and function of very large biological systems, such as a clarified thick coronal slab of human brain and uniformly expanded tissues, and also for rapid volumetric calcium imaging of highly motile animals, such as Hydra, undergoing non-isomorphic body shape changes.

Published

2018

2. Whole-brain mapping reveals the divergent impact of ketamine on the dopamine system

Author

Malika S. Datta, Yannan Chen, Shradha Chauhan, Jing Zhang, Estanislao Daniel De La Cruz, Cheng Gong, and Raju Tomer

Abstract

Ketamine is a multifunctional drug with clinical applications as an anesthetic, as a pain management medication and as a transformative fast-acting antidepressant. It is also abused as a recreational drug due to its dissociative property. Recent studies in rodents are revealing the neuronal mechanisms that mediate the complex actions of ketamine, however, its long-term impact due to prolonged exposure remains much less understood with profound scientific and clinical implications. Here, we develop and utilize a high-resolution whole-brain phenotyping approach to show that repeated ketamine administration leads to a dosage-dependent decrease of dopamine (DA) neurons in the behavior state-related midbrain regions and, conversely, an increase within the hypothalamus. Congruently, we show divergently altered innervations of prefrontal cortex, striatum, and sensory areas. Further, we present supporting data for the post-transcriptional regulation of ketamine-induced structural plasticity. Overall, through an unbiased whole-brain analysis, we reveal the divergent brain-wide impact of chronic ketamine exposure on the association and sensory pathways.

Published

2023

3. Molecularly defined cortical astroglia subpopulation modulates neurons via secretion of Norrin

Author

J. Gavin Daigle, Dwight E. Bergles, Raha Dastgheyb, Jeannie Chew, Svetlana Vidensky, Malika S Datta, Rita Sattler, Namho Kim, Justin Hanes, Yi Chun Hsieh, Mikhail V. Pletnikov, Jeffrey D. Rothstein, Michael B. Robinson, Raju Tomer, Norman J. Haughey, Thomas Philips, Jung Soo Suk, Zhuoxun Chen, Jacqueline T. Pham, Sean J. Miller, and Ethan G. Hughes

Subjects

0301 basic medicine, Genetically modified mouse, Male, Dendritic spine, Transgene, Dendritic Spines, Mice, Transgenic, Nerve Tissue Proteins, Biology, Article, Receptors, G-Protein-Coupled, Transcriptome, 03 medical and health sciences, 0302 clinical medicine, Premovement neuronal activity, Animals, Humans, Secretion, Gray Matter, Receptor, Eye Proteins, Cells, Cultured, Cerebral Cortex, Neurons, LGR6, General Neuroscience, Motor Cortex, Mice, Inbred C57BL, 030104 developmental biology, nervous system, Astrocytes, Neuroscience, 030217 neurology & neurosurgery

Abstract

Despite expanding knowledge regarding the role of astroglia in regulating neuronal function, little is known about regional or functional subgroups of brain astroglia and how they may interact with neurons. We use an astroglia-specific promoter fragment in transgenic mice to identify an anatomically defined subset of adult gray matter astroglia. Using transcriptomic and histological analyses, we generate a combinatorial profile for the in vivo identification and characterization of this astroglia subpopulation. These astroglia are enriched in mouse cortical layer V; express distinct molecular markers, including Norrin and leucine-rich repeat-containing G-protein-coupled receptor 6 (LGR6), with corresponding layer-specific neuronal ligands; are found in the human cortex; and modulate neuronal activity. Astrocytic Norrin appears to regulate dendrites and spines; its loss, as occurring in Norrie disease, contributes to cortical dendritic spine loss. These studies provide evidence that human and rodent astroglia subtypes are regionally and functionally distinct, can regulate local neuronal dendrite and synaptic spine development, and contribute to disease.

Published

2019

4. Light Sheet Theta Microscopy for High-resolution Quantitative Imaging of Large Biological Systems

Author

Bianca Migliori, Malika S. Datta, Christophe Dupre, Mehmet C. Apak, Shoh Asano, Ruixuan Gao, Edward S. Boyden, Ola Hermanson, Rafael Yuste, and Raju Tomer

Subjects

Quantitative imaging, Optics, Planar Imaging, Materials science, Image quality, business.industry, Light sheet fluorescence microscopy, Microscopy, High resolution, business, Scaling, Characterization (materials science)

Abstract

Advances in tissue clearing and molecular labelling methods are enabling unprecedented optical access to large intact biological systems. These advances fuel the need for high-speed microscopy approaches to image large samples quantitatively and at high resolution. While Light Sheet Microscopy (LSM), with its high planar imaging speed and low photo-bleaching, can be effective, scaling up to larger imaging volumes has been hindered by the use of orthogonal light-sheet illumination. To address this fundamental limitation, we have developed Light Sheet Theta Microscopy (LSTM), which uniformly illuminates samples from same side as the detection objective, thereby eliminating limits on lateral dimensions without sacrificing imaging resolution, depth and speed. We present detailed characterization of LSTM, and show that this approach achieves rapid high-resolution imaging of large intact samples with superior uniform high-resolution than LSM. LSTM is a significant step in high-resolution quantitative mapping of structure and function of large intact biological systems.

Published

2017