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Autism

Autism

Höfundur Mirolyuba Ilieva; Wai Lau

Útgefandi Elsevier S & T

Snið Page Fidelity

Print ISBN 9780128212424

Útgáfa 1

Útgáfuár 2020

19.990 kr.

Description

Efnisyfirlit

  • Autism
  • Copyright
  • Contents
  • Contributors
  • Preface
  • Chapter One: The putative etiology and prevention of autism
  • 1. Background
  • 2. Glia
  • 3. Astrocytes and microglia (CNS)
  • 4. Oligodendrocytes (CNS)
  • 5. Schwann cells (PNS)
  • 6. Myelination and IGF-1
  • 7. Autism etiology
  • 8. Connectivity
  • 9. Polymorphism and biomarkers
  • 10. Autism prevention
  • 11. Challenge
  • Acknowledgments
  • References
  • Chapter Two: Role of environmental factors and epigenetics in autism spectrum disorders
  • 1. Context: Genetics yes, but not only
  • 2. Environmental factors
  • 2.1. Maternal stress during pregnancy and ASD
  • 2.1.1. Infections
  • 2.1.2. Air pollutants
  • 2.1.3. Organochlorides (OC) and organophosphates (OP) pesticides
  • 2.1.4. Psychological stress
  • 2.1.5. Anti-epileptic drug valproic acid
  • 2.1.6. Folate (vitamine B9) supplementation
  • 2.2. Developmental sensitivity windows
  • 3. Environmental animal models for ASD
  • 3.1. Anti-epileptic drug VPA rodent model
  • 3.2. Maternal infections models
  • 3.3. Exposure to pesticides models
  • 3.4. Maternal psychological (social) stress model
  • 4. Epigenetics mechanisms: The examples of valproate and folate
  • 4.1. Indirectly through the γ-aminobutyric acid (GABA)-ergic system
  • 4.2. Directly through the inhibition of histone deacetylase
  • 4.3. The transgenerational epigenetic inheritance
  • 4.4. Folate and epigenetics mechanisms
  • 5. Conclusion
  • References
  • Chapter Three: Genomics, transcriptomics, proteomics and big data analysis in the discovery of new d
  • 1. Introduction
  • 2. Omics and big data studies of autism spectrum disorder
  • 2.1. Immune and inflammation pathways
  • 2.2. Synapse and neurodevelopment
  • 2.3. Mitochondrial energy metabolism
  • 2.4. Lipid transport and metabolism
  • 2.5. Gut microbiome
  • 2.6. Ubiquitin-proteasome system
  • 2.7. Epigenetic regulation
  • 2.8. Big data analysis with machine learning approach
  • 3. Conclusions and future directions in the biomarker and therapy discovery based on -omics and big
  • Conflict of interest
  • References
  • Chapter Four: Autism spectrum disorder risk prediction: A systematic review of behavioral and neural
  • 1. Introduction
  • 1.1. Early behavioral signs of ASD
  • 1.2. Early neuroimaging derived signs of ASD
  • 1.2.1. Morphological signs using structural and diffusion MRI
  • 1.2.2. Neural activities with functional MRI
  • 1.2.3. Neurophysiological signs measured by EEG
  • 2. Methods
  • 2.1. Scope of the review
  • 2.2. Modalities and features
  • 2.3. Analytical methods
  • 3. Results
  • 3.1. Screening tools
  • 3.1.1. Screening tools for the general population
  • 3.1.2. Screening tools for the high-risk population
  • 3.2. Observational and experimental studies
  • 3.3. Structural MRI
  • 3.4. Functional MRI
  • 3.5. EEG and ERP
  • 4. Discussion
  • 4.1. Summary of behavioral based prediction
  • 4.2. Summary of neuroimaging based prediction
  • 4.3. Issues in existing prediction studies
  • 4.4. Future directions
  • References
  • Chapter Five: Resting-state abnormalities of posterior cingulate in autism spectrum disorder
  • 1. Anatomy of the PCC
  • 2. Structural connectivity of the PCC
  • 3. Resting state fMRI: Intrinsic connectivity networks
  • 4. The PCC as the central hub in DMN
  • 5. ASD
  • 6. Local resting state abnormality of the PCC in ASD
  • 7. Long-range resting state abnormality of the PCC in ASD
  • 8. Importance of local underconnectivity of the dorsal PCC in ASD
  • 8.1. Cognitive inflexibility
  • 8.2. Impaired social-emotional processing
  • 9. Importance of the PCC-MPFC hypoconnectivity in ASD
  • 9.1. Disturbed large-scale cortical integration
  • 9.2. Impaired cognitive performance
  • 9.3. Impaired social cognition
  • 10. Future directions
  • References
  • Chapter Six: Neurobiology of sensory processing in autism spectrum disorder
  • 1. Introduction
  • 2. Atypical sensory processing in ASD
  • 3. Vestibular system
  • 4. Somatosensory system
  • 5. Visual system
  • 6. Auditory system
  • 7. Olfactory and gustatory systems
  • 8. Neuroplasticity and sensory integration
  • 9. Conclusion
  • Acknowledgment
  • References
  • Chapter Seven: The role of the endocannabinoid system in autism spectrum disorders: Evidence from mo
  • 1. Animal models of autism spectrum disorder (ASD)
  • 2. Understanding the etiopathology of ASD: The role of the endocannabinoid system
  • 3. Alterations of ECS in animal models of ASD: Toward novel therapeutic approaches
  • 4. ASD-like phenotypes induced by manipulations of the ECS: Relevance for designing animal models of
  • 5. Conclusions and perspectives
  • References
  • Chapter Eight: The effects of oxytocin administration on individuals with ASD: Neuroimaging and beha
  • 1. Introduction
  • 2. Oxytocin
  • 2.1. Brain-based studies of oxytocin administration in neurotypical individuals
  • 3. Oxytocin and ASD
  • 4. Oxytocin administration in individuals with ASD
  • 4.1. Behavioral findings of oxytocin administration in individuals with ASD
  • 4.2. Brain-based findings of oxytocin administration in individuals with ASD
  • 5. Discussion
  • 5.1. Future directions
  • 6. Conclusions
  • References
  • Chapter Nine: Microglia in animal models of autism spectrum disorders
  • 1. Introduction
  • 2. Animal models of ASDs
  • 2.1. Genetic animal models (Table 1)
  • 2.1.1. Fmr1 (fragile X mental retardation 1)
  • 2.1.2. Mecp2 (methyl-CpG binding protein 2)
  • 2.1.3. Tsc1/2 (tuberous sclerosis proteins1/2)
  • 2.1.4. Shank3 (SH3 and multiple ankyrin repeat domains 3)
  • 2.1.5. Pten (phosphatase and tensin homolog deleted from chromosome 10)
  • 2.1.6. Cntnap2 (contactin-associated protein-like 2)
  • 2.1.7. Scn1a (sodium voltage-gated channel alpha subunit 1)
  • 2.1.8. 15q11-13 duplicate
  • 2.2. Genetic animal models targeting genes which are not related to symptomatic autism (Table 1)
  • 2.2.1. Nlgn3/4 (Neuroligin3/4)
  • 2.2.2. Nrx1 (neurexin1)
  • 2.2.3. Shank (SH3 and multiple ankyrin repeat domains protein)
  • 2.2.4. Parvalbumin
  • 2.3. Animal models created by environmental manipulations (Table 2)
  • 2.3.1. Valproic acid administration
  • 2.3.2. Maternal immune activation
  • 2.3.2.1. LPS administration
  • 2.3.2.2. Poly(I:C) administration
  • 3. Animal models of ASD exhibiting possible microglia involvement
  • 3.1. Genetic animal models (Table 1)
  • 3.1.1. Fmr1 knockout
  • 3.1.2. Cx3cr1 knockout
  • 3.1.3. BTBR mice
  • 3.1.4. patDp/+ mice
  • 3.1.5. Mecp2
  • 3.2. Animal models using environmental manipulations to induce disease (Table 2)
  • 3.2.1. IL-6 administration
  • 3.2.2. LPS administration
  • 3.2.3. Poly(I:C) administration
  • 3.2.4. Air pollution
  • 3.2.5. Ovalbumin administration
  • 3.3. Possible animal models of ASD (Table 3)
  • 3.3.1. Trem2 knockout
  • 3.3.2. Atg7 knockout
  • 3.3.3. CSF1-CSF1R signaling deficiency
  • 3.4. Non-rodent animal models of ASDs (Table 4)
  • 3.4.1. Marmoset
  • 3.4.2. Pig
  • 4. Treatment of ASDs by controlling microglial functions
  • 5. Conclusion
  • References
  • Chapter Ten: The early overgrowth theory of autism spectrum disorder: Insight into convergent mechan
  • 1. Introduction
  • 2. The early overgrowth theory of ASD
  • 3. Valproic acid and ASD
  • 3.1. Epidemiological evidence
  • 3.2. The VPA animal model of ASD
  • 4. VPA and the cellular and molecular mechanisms of early overgrowth
  • 4.1. Modulation of functional systems
  • 4.1.1. Gamma-aminobutyric acid (GABA)
  • 4.1.2. Glutamate
  • 4.1.3. Serotonin
  • 4.1.4. Dopamine
  • 4.1.5. Brain-derived neurotrophic factor
  • 5. Concluding remarks and future directions
  • Acknowledgments
  • References
  • Chapter Eleven: The role of neuroglia in autism spectrum disorders
  • 1. Autism spectrum disorders
  • 2. Etiology of autism spectrum disorders
  • 3. Molecular aspects of autism spectrum disorders
  • 4. Neuroglia in autism spectrum disorders
  • 4.1. Neuroglia: Homeostatic cells of the CNS
  • 4.1.1. Microglia
  • 4.1.2. Astrocytes
  • 4.2. The role of neuroglia in autism spectrum disorders
  • 4.2.1. Neuroglia and ASD genes
  • 4.2.2. Neuroglia reactivity and immune response in ASD
  • 4.2.3. Neuroglia and glutamate excitotoxicity in ASD
  • 4.2.4. Neuroglia and environmental factors in ASD
  • 4.3. Mapping neuroglia in a preclinical rodent model of ASD
  • 5. Conclusions
  • References
  • Chapter Twelve: Oxidative stress, metabolic and mitochondrial abnormalities associated with autism s
  • 1. Etiology of autism spectrum disorder
  • 2. Oxidative stress and ASD
  • 2.1. Where are reactive oxygen species produced?
  • 2.2. Antioxidative systems
  • 2.2.1. Superoxide dismutase
  • 2.2.2. Catalase
  • 2.2.3. Glutathione peroxidase
  • 2.2.4. Glutathione
  • 2.3. Oxidative stress and the brain
  • 3. Metabolic abnormalities and ASD
  • 3.1. The methylation cycle
  • 3.2. The transsulfuration pathway
  • 3.3. Abnormalities in other nutrients
  • 4. Mitochondrial abnormalities and ASD
  • 5. A unified framework
  • 6. Comorbidity
  • 7. Future treatment options
  • References
  • Chapter Thirteen: In vitro models for ASD-patient-derived iPSCs and cerebral organoids
  • 1. Modeling human neurodevelopment in vitro
  • 1.1. Pluripotent stem cells
  • 1.2. Generation of PSC-derived neural cells
  • 1.3. Utilizing iPSC technology in the study of ASD
  • 1.3.1. Neural progenitor cells
  • 1.3.2. Neurons
  • 1.3.3. Glial cells
  • 1.4. The progression from 2D to 3D models
  • 1.5. Utilizing cerebral organoid models in the study of ASD
  • 2. CRISPR/Cas9 and iPSC technologies
  • 3. Limitations and future directions
  • References
  • Index
  • Back Cover

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