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181   $ctxt$2rdacontent
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200 00$aSpaceflight and the central nervous system $eclinical and scientific aspects /$fedited by Alex P. Michael [and three others]
210  1$aCham, Switzerland :$cSpringer,$d[2023]
210  4$d©2023
215   $a1 online resource (139 pages)
300   $aIncludes index.
311 08$aPrint version: Michael, Alex P. Spaceflight and the Central Nervous System Cham : Springer International Publishing AG,c2023 9783031184390 
327   $aIntro -- Contents -- 1: History of Spaceflight and the Central Nervous System -- Introduction -- Early Discoveries -- Early Rocket Science -- Early Space Exploration -- The Soviet Union -- The United States -- Early Space Stations -- International Cooperation -- Development of International Organizations -- The International Space Station -- History of Spaceflight Medicine -- Aerospace Medicine Organizations -- Initial Spaceflight Medical Problems -- Long-Duration Spaceflight -- Conclusion -- References -- 2: Cardiovascular Physiology and Fluid Shifts in Space -- The Cardiovascular System on Earth and in Space -- General Concepts of the Circulatory System on Earth and in Space -- Basic Concepts of Blood-Brain Barrier -- Adaptations to Microgravity -- Acute Adaptations and Microgravity-Induced Fluid Shift -- Long-Term Adaptations -- Circulation and the Central Nervous System -- Endothelial Dysfunction -- CSF Hydrodynamics and Brain and Neck Venous Congestion -- CSF Hydrodynamics Circulation on Earth and in Space -- Brain and Neck Venous Congestion -- Space Adaptation Syndrome (SMS) -- Visual Impairment Intracranial Pressure Syndrome -- Integrated Physiologic Countermeasures -- Artificial Gravity -- Lower Body Negative Pressure With and Without Exercise -- Coagulation and LBNP -- Sodium Intake -- References -- 3: Effects of Microgravity and Space Radiation on the Nervous System -- Introduction -- Effects of Microgravity on Neurobiology -- Spaceflight-Induced Intracranial Hypertension -- Space Motion Sickness -- Radiological Changes (Magnetic Resonance Imaging) in Brain Tissue After Microgravity Exposure -- Effects of Microgravity on the Vestibular System -- Effects of Space Radiation on the Nervous System -- Conclusion -- References -- 4: Cognitive Performance and Neuromapping -- Overview -- Cognitive Assessment Approaches.
327   $aElemental Cognitive Tasks -- Complex Operationally Relevant Tasks -- Considerations for Cognitive Assessment in Space -- Adaptation to the Spaceflight Environment and Early Cognitive Effects -- Cognition During Long-Duration Spaceflight -- Perceptual and Motor Systems -- Spatial Cognition -- Memory and Learning -- Attention -- Executive and Higher Cognitive Functions -- Cognitive Processing of Emotional Stimuli -- Cognitive Processing of Social Stimuli -- Operationally Relevant Performance -- Cognition upon Return to Earth -- Neuromapping -- Summary -- Potential Positive Effects -- Risk Mitigation Strategies -- Future Directions -- References -- 5: Spine Biomechanics and Pathology -- History of Back Pain and Spinal Injury Associated with Spaceflight -- Comparing Epidemiology of Spaceflight-Related Low Back Pain to Terrestrial Low Back Pain -- Spinal Anatomy Affected by Gravitational Load -- Intervertebral Discs -- Paraspinal Muscles -- Changes in Spinal Biomechanics During and After Spaceflight -- Backpain and Spaceflight -- Pain Pathways for Low Back Pain -- Potential Pain Pathways Associated with Back Pain During Spaceflight -- Other Factors Contributing to Back Pain During Spaceflight -- Pain Pathways Associated with Back Pain Following Spaceflight -- Risk Factors for Spine Injury or Pain -- Associating Symptoms and Pathology Using Imaging -- Treatment Possibilities -- Preflight Surveillance -- Astronaut-Specific Inflight Exercise and Postflight Rehab -- Inflight Spinal Assessment and Intervention -- Clinical Impact of Spine Health in Spaceflight -- References -- 6: Vestibular System -- Introduction -- Vestibular System Anatomy and Physiology -- The Vestibular Labyrinth -- Vestibular Reflex Function -- Central Vestibular Processing -- Vestibular System Compensation -- History of Vestibular System Evaluation in Spaceflight.
327   $aTechniques Used to Study the Vestibular System in Microgravity -- Animal Models -- Earth-Bound Models -- Methodology -- Effects of Microgravity on the Vestibular System -- Otolith Function -- Semicircular Canal Function -- Postural Stability and Sensorimotor Responses -- Oculomotor Function -- Other Consideration -- Space Motion Sickness -- Perceptual Changes in Microgravity -- Post-Spaceflight Vestibular Adaptation -- Future Directions -- References -- 7: Intraocular Pressure Considerations -- What Is Spaceflight-Associated Neuro-ocular Syndrome (SANS)? -- Fluid Shifts and SANS -- Intraocular Pressure and SANS -- IOP Conceptual Model: Ocular Pressure-Volume -- Aqueous Humor Dynamics and Regulation of IOP (Fig. 7.2) -- IOP in Relation to Ocular Volume -- IOP and Postural Changes -- IOP and Ocular Perfusion Pressure -- IOP, CSFp, and Translaminar Pressure Difference (TLPD) -- Orbital Pressure and IOP -- Autonomic and Central Regulation of IOP -- Circadian Changes -- IOP Changes in Space -- IOP in Microgravity Models -- Ground-Based Analogs -- Head-Down Tilt (HDT) Bed Rest -- Dry Immersion -- Countermeasures -- Exercise -- Lower Body Negative Pressure (LBNP) -- Artificial Gravity -- Animal Models -- Animal Experiments in Space -- Animal Ground Models -- Non-invasive IOP Measurement and Devices -- Future Directions for In-Flight Studies and Ground studies -- References -- 8: Central Nervous System Neoplasms in Microgravity -- Introduction -- Environment -- Microgravity -- Space Radiations -- CNS Neoplasms Overview -- Methodology of Studying CNS Neoplastic Behavior in Space -- CNS Neoplasms Behavior in Space -- Carcinogenesis in Space -- Tumor Suppression in Space: A Dual Theory -- History of Literature -- Literature Review Methodology -- Limitations -- Conclusion -- References -- 9: Space Renaissance and Neurodegeneration.
327   $aIntroduction: A Brief History of Space Exploration -- Neurodegeneration and Neuroinflammation -- iPSC Modeling and CNS Organoids to Study Neurodegenerative Diseases -- The Effects of Microgravity on Immune and Brain Cells -- Enabling Human Cell Cultures in LEO: Engineering Meets Cell Biology -- Pioneering Experiments with MS and PD Brain Organoids in LEO -- Challenges and Future Perspectives -- References -- 10: Summary and Future Directions -- Introduction -- Establishing Crew Health and Performance Standards -- Developing Methods of Meeting Standards -- Future Missions -- References -- Index.
606   $aSpace flight$xPhysiological effect
615  0$aSpace flight$xPhysiological effect.
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702   $aMichael$b Alex P.
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