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Macrophages. --- Histiocytes --- Mononuclear phagocytes --- Antigen presenting cells --- Connective tissue cells --- Killer cells --- Phagocytes --- Reticulo-endothelial system

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We have entered a new era where some concepts of the complex community of microorganisms (microbiota comprising bacteria, fungi, viruses, bacteriophages and helminths) are being re-discovered and re-visited. Microbiota and human interaction is not new; they have shared a long history of co-existence. Nevertheless, the opportunities to understand the role of these microorganisms in human diseases and to design a potential treatment were limited. At present, thanks to development of innovative and cutting-edge molecular biological and microbiological technologies as well as clinical informatics and bioinformatics skills, microbiome application is moving into clinics. Approaches to therapy based on prebiotics, probiotics and lately on fecal microbiota transplantation has revolutionized medicine. Microbiota outnumbers our genes and is now regarded as another organ of the body. The gastrointestinal tract and gut microbiota display a well-documented symbiotic relationship. Disruption of intestinal microbiota homeostasis—called dysbiosis—has been associated with several diseases. Whether dysbiosis is a cause or consequence of disease initiation and progression still needs to be investigated in more depth. The aim of this book is to highlight recent advances in the field of microbiome research, which are now shaping medicine, and current approaches to microbiome-oriented therapy for gastrointestinal diseases. Dr. Rinaldo Pellicano Dr. Sharmila Fagoonee Guest Editors

Bacteroides ovatus --- Bifidobacterium adolescentis --- Dysbiosis --- Faecalibacterium prausnitzii --- Ruminococcus gnavus --- type 1 diabetes --- microbiota --- microbiome --- auto-immunity --- gut permeability --- gut --- IBS --- celiac disease --- enteropathy --- gluten --- therapy --- gut microbiota --- precision medicine --- Clostridium difficile --- inflammatory bowel disease --- ulcerative colitis --- irritable bowel disease --- metabolic syndrome --- gastric microbiota --- transient --- persistent --- culture --- sequencing --- Helicobacter pylori --- fecal microbiota transplantation --- feces donor --- fecal microbiota --- flow cytometry --- viability of bacteria --- next-generation sequencing --- culturing of fecal microbiota --- Alzheimer’s disease --- microbiota–gut–brain axis --- neurodegenerative disease --- intestinal flora --- necrotizing enterocolitis --- intestinal microbiology --- infant gut --- metabolomics --- IL-6 --- IL-8 --- IL-12p70 --- intestinal permeability --- zonulin --- gut virome --- steatosis --- cirrhosis --- hepatocellular carcinoma --- gastrointestinal --- technology --- high-throughput --- crohn’s disease --- mononuclear cells --- transient receptor potential channel --- pancreatic diseases --- acute pancreatitis --- chronic pancreatitis --- diabetes mellitus --- pancreatic ductal adenocarcinoma --- pancreatic cystic neoplasms

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Dear Colleagues, The brain is vulnerable to injury. Following injury in the brain, apoptosis or necrosis may occur easily, leading to various functional disabilities. Neuronal death is associated with a number of neurological disorders including hypoxic ischemia, epileptic seizures, and neurodegenerative diseases. The brain subjected to injury is regarded to be responsible for the alterations in neurotransmission processes, resulting in functional changes. Oxidative stress produced by reactive oxygen species has been shown to be related to the death of neurons in traumatic injury, stroke, and neurodegenerative diseases. Therefore, scavenging or decreasing free radicals may be crucial for preventing neural tissues from harmful adversities in the brain. Neurotrophic factors, bioactive compounds, dietary nutrients, or cell engineering may ameliorate the pathological processes related to neuronal death or neurodegeneration and appear beneficial for improving neuroprotection. As a result of neuronal death or neuroprotection, the brain undergoes activity-dependent long-lasting changes in synaptic transmission, which is also known as functional plasticity. Neuroprotection implying the rescue from neuronal death is now becoming one of global health concerns. This Special Issue attempts to explore the recent advances in neuroprotection related to the brain. This Special Issue welcomes original research or review papers demonstrating the mechanisms of neuroprotection against brain injury using in vivo or in vitro models of animals as well as in clinical settings. The issues in a paper should be supported by sufficient data or evidence. Prof. Bae Hwan Lee Guest Editor

Research & information: general --- global cerebral ischemia --- amiloride --- sodium-hydrogen exchanger-1 --- zinc --- neuronal death --- neuroprotection --- neurodegenerative disorder --- choline acetyltransferase (ChAT) --- trimethyltin (TMT) --- bean phosphatidylserine (Bean-PS) --- brain-derived neurotrophic factor --- moderate hypoxia --- physical exercise --- psychomotor function --- reaction time --- cortisol --- catecholamines --- nitrite --- endotheline-1 --- lactate --- pyridoxine deficiency --- ischemia --- gerbil --- homocysteine --- cell death --- glia --- neurogenesis --- N-acetyl-l-cysteine --- transient receptor potential melastatin 2 --- neurodegeneration --- Alzheimer's disease --- metabolic disease --- adiponectin --- insulin --- antioxidants --- stroke --- preventive gene therapy --- adenoviral vector --- VEGF --- GDNF --- NCAM --- human umbilical cord blood mononuclear cells --- antioxidant --- brain --- neurodegenerative disease --- oxidative stress --- PGC-1α --- vascular endothelial growth factor --- vascular endothelial growth factor receptor 2 --- PI3K/AKT --- MEK/ERK --- status epilepticus --- hippocampus --- middle cerebral artery occlusion --- reperfusion injury --- lipid emulsion --- excitotoxicity --- apoptosis --- GPR4 receptor --- MPP+ --- Parkinson's disease --- CRISPR/cas9 --- ischemic stroke --- blood brain barrier --- nanoparticle-based drug delivery --- brain targeting --- BDNF --- miRNAs --- synaptic plasticity --- depression --- glioblastoma --- astrocytes --- astrocytic networks --- connexin 43 --- calcium activity --- neural injury --- nimodipine --- subarachnoid haemorrhage --- acid-sensing ion channels --- oxygen-glucose deprivation --- liver growth factor --- inflammation --- microglia --- Tg2576 transgenic mice --- amyloid-beta --- oculomotor system --- trophic factors --- motoneurons --- axotomy --- amyotrophic lateral sclerosis --- electroneutral transport --- cation-chloride cotransporters --- KCCs --- NKCCs --- WNK-SPAK/OSR1 --- ascorbic acid --- aging --- organotypic hippocampal slice culture --- global cerebral ischemia --- amiloride --- sodium-hydrogen exchanger-1 --- zinc --- neuronal death --- neuroprotection --- neurodegenerative disorder --- choline acetyltransferase (ChAT) --- trimethyltin (TMT) --- bean phosphatidylserine (Bean-PS) --- brain-derived neurotrophic factor --- moderate hypoxia --- physical exercise --- psychomotor function --- reaction time --- cortisol --- catecholamines --- nitrite --- endotheline-1 --- lactate --- pyridoxine deficiency --- ischemia --- gerbil --- homocysteine --- cell death --- glia --- neurogenesis --- N-acetyl-l-cysteine --- transient receptor potential melastatin 2 --- neurodegeneration --- Alzheimer's disease --- metabolic disease --- adiponectin --- insulin --- antioxidants --- stroke --- preventive gene therapy --- adenoviral vector --- VEGF --- GDNF --- NCAM --- human umbilical cord blood mononuclear cells --- antioxidant --- brain --- neurodegenerative disease --- oxidative stress --- PGC-1α --- vascular endothelial growth factor --- vascular endothelial growth factor receptor 2 --- PI3K/AKT --- MEK/ERK --- status epilepticus --- hippocampus --- middle cerebral artery occlusion --- reperfusion injury --- lipid emulsion --- excitotoxicity --- apoptosis --- GPR4 receptor --- MPP+ --- Parkinson's disease --- CRISPR/cas9 --- ischemic stroke --- blood brain barrier --- nanoparticle-based drug delivery --- brain targeting --- BDNF --- miRNAs --- synaptic plasticity --- depression --- glioblastoma --- astrocytes --- astrocytic networks --- connexin 43 --- calcium activity --- neural injury --- nimodipine --- subarachnoid haemorrhage --- acid-sensing ion channels --- oxygen-glucose deprivation --- liver growth factor --- inflammation --- microglia --- Tg2576 transgenic mice --- amyloid-beta --- oculomotor system --- trophic factors --- motoneurons --- axotomy --- amyotrophic lateral sclerosis --- electroneutral transport --- cation-chloride cotransporters --- KCCs --- NKCCs --- WNK-SPAK/OSR1 --- ascorbic acid --- aging --- organotypic hippocampal slice culture

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Dear Colleagues, The brain is vulnerable to injury. Following injury in the brain, apoptosis or necrosis may occur easily, leading to various functional disabilities. Neuronal death is associated with a number of neurological disorders including hypoxic ischemia, epileptic seizures, and neurodegenerative diseases. The brain subjected to injury is regarded to be responsible for the alterations in neurotransmission processes, resulting in functional changes. Oxidative stress produced by reactive oxygen species has been shown to be related to the death of neurons in traumatic injury, stroke, and neurodegenerative diseases. Therefore, scavenging or decreasing free radicals may be crucial for preventing neural tissues from harmful adversities in the brain. Neurotrophic factors, bioactive compounds, dietary nutrients, or cell engineering may ameliorate the pathological processes related to neuronal death or neurodegeneration and appear beneficial for improving neuroprotection. As a result of neuronal death or neuroprotection, the brain undergoes activity-dependent long-lasting changes in synaptic transmission, which is also known as functional plasticity. Neuroprotection implying the rescue from neuronal death is now becoming one of global health concerns. This Special Issue attempts to explore the recent advances in neuroprotection related to the brain. This Special Issue welcomes original research or review papers demonstrating the mechanisms of neuroprotection against brain injury using in vivo or in vitro models of animals as well as in clinical settings. The issues in a paper should be supported by sufficient data or evidence. Prof. Bae Hwan Lee Guest Editor

global cerebral ischemia --- amiloride --- sodium–hydrogen exchanger-1 --- zinc --- neuronal death --- neuroprotection --- neurodegenerative disorder --- choline acetyltransferase (ChAT) --- trimethyltin (TMT) --- bean phosphatidylserine (Bean-PS) --- brain-derived neurotrophic factor --- moderate hypoxia --- physical exercise --- psychomotor function --- reaction time --- cortisol --- catecholamines --- nitrite --- endotheline-1 --- lactate --- pyridoxine deficiency --- ischemia --- gerbil --- homocysteine --- cell death --- glia --- neurogenesis --- N-acetyl-l-cysteine --- transient receptor potential melastatin 2 --- neurodegeneration --- Alzheimer’s disease --- metabolic disease --- adiponectin --- insulin --- antioxidants --- stroke --- preventive gene therapy --- adenoviral vector --- VEGF --- GDNF --- NCAM --- human umbilical cord blood mononuclear cells --- antioxidant --- brain --- neurodegenerative disease --- oxidative stress --- PGC-1α --- vascular endothelial growth factor --- vascular endothelial growth factor receptor 2 --- PI3K/AKT --- MEK/ERK --- status epilepticus --- hippocampus --- middle cerebral artery occlusion --- reperfusion injury --- lipid emulsion --- excitotoxicity --- apoptosis --- GPR4 receptor --- MPP+ --- Parkinson’s disease --- CRISPR/cas9 --- ischemic stroke --- blood brain barrier --- nanoparticle-based drug delivery --- brain targeting --- BDNF --- miRNAs --- synaptic plasticity --- depression --- glioblastoma --- astrocytes --- astrocytic networks --- connexin 43 --- calcium activity --- neural injury --- nimodipine --- subarachnoid haemorrhage --- acid-sensing ion channels --- oxygen-glucose deprivation --- liver growth factor --- inflammation --- microglia --- Tg2576 transgenic mice --- amyloid-beta --- oculomotor system --- trophic factors --- motoneurons --- axotomy --- amyotrophic lateral sclerosis --- electroneutral transport --- cation-chloride cotransporters --- KCCs --- NKCCs --- WNK-SPAK/OSR1 --- ascorbic acid --- aging --- organotypic hippocampal slice culture --- n/a --- sodium-hydrogen exchanger-1 --- Alzheimer's disease --- Parkinson's disease