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Starting from a kinase of interest, AMP-activated protein kinase (AMPK) has gone far beyond an average biomolecule. Being expressed in all mammalian cell types and probably having a counterpart in every eukaryotic cell, AMPK has attracted interest in virtually all areas of biological research. Structural and biophysical insights have greatly contributed to a molecular understanding of this kinase. From good old protein biochemistry to modern approaches, such as systems biology and advanced microscopy, all disciplines have provided important information. Thus, multiple links to cellular events and subcellular localizations have been established. Moreover, the crucial involvement of AMPK in human health and disease has been evidenced. AMPK accordingly has moved from an interesting enzyme to a pharmacological target. However, despite our extensive current knowledge about AMPK, the growing community is busier than ever. This book provides a snapshot of recent and current AMPK research with an emphasis on work providing molecular insight, including but not limited to novel physiological and pathological functions, or regulatory mechanisms. Up-to-date reviews and research articles are included.
n/a --- HDACs --- transcription --- epigenetics --- spermatozoa --- par complex --- A769662 --- MDCK --- skeletal muscle --- AID --- phosphorylation --- energy metabolism --- monocytes --- autophagy --- CML --- liver --- hindlimb suspension --- pregnancy --- preeclampsia --- gestational diabetes mellitus --- CaMKK2 --- assisted reproduction techniques --- nutrient-sensing signals --- sonic hedgehog --- protein acetylation --- glycogen storage disease --- AMPK --- adenosine monophosphate-activated protein kinase --- AICAR --- indirect calorimetry --- IL-1? --- MyHC I(?) --- HDAC4/5 --- endothelial cells --- infection --- hepatocyte --- p70S6K --- lipid metabolism --- host defense --- exercise --- kidney disease --- heat shock protein --- ?RIM --- mycobacteria --- activation loop --- developmental origins of health and disease (DOHaD) --- CREB --- TAK1 --- metabolic-inflammation --- phenylephrine --- AMP-activated protein kinase (AMPK) --- KATs --- 2-methoxyestradiol --- DNA methylation --- NLRP3 --- pump --- ?-linker --- steatosis --- AMPK kinase --- stress --- endothelial nitric-oxide synthase --- vasodilation --- adherent junctions --- epithelial cells --- glycogen --- Akt --- synaptic activation --- cellular energy sensing --- glucose uptake --- transporter --- co-expression --- atrophy --- nutrigenomics --- motility --- vasoconstriction --- fatty acid oxidation --- oxidative stress --- AS160 --- membrane --- histone modification --- sirtuin 1 (SIRT1) --- chromatin remodeling --- insulin signalling --- dietary fatty acids --- ULK --- CMML --- adaptive thermogenesis --- mTOR --- MDS --- mechanical unloading --- AML --- endothelial function --- medulloblastoma --- PKA --- adipose tissue --- NAD+ --- membranes --- nutrition --- ZO-1 --- TBC1D4 --- adipocyte --- soluble Adenylyl cyclase --- metabolism --- renin-angiotensin system --- energy utilization --- proteasome --- differentiation --- signaling --- peroxisome proliferator-activated receptor gamma coactivator 1-? (PGC1?) --- hypertrophy --- AMP-activated protein kinase --- metabolic disease --- LKB1 --- soleus muscle --- macrophages --- Immediate early genes --- CBS --- beiging --- motor endplate remodeling --- ionomycin --- nectin-afadin --- tight junctions --- resveratrol --- protein kinase B --- regrowth --- mitochondria --- protein synthesis --- energy deficiency --- catechol-O-methyltransferase --- fiber-type --- microarrays --- carrier --- acetyl-CoA --- hypertension --- 3T3-L1 --- hypothalamus --- food intake --- benign
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Starting from a kinase of interest, AMP-activated protein kinase (AMPK) has gone far beyond an average biomolecule. Being expressed in all mammalian cell types and probably having a counterpart in every eukaryotic cell, AMPK has attracted interest in virtually all areas of biological research. Structural and biophysical insights have greatly contributed to a molecular understanding of this kinase. From good old protein biochemistry to modern approaches, such as systems biology and advanced microscopy, all disciplines have provided important information. Thus, multiple links to cellular events and subcellular localizations have been established. Moreover, the crucial involvement of AMPK in human health and disease has been evidenced. AMPK accordingly has moved from an interesting enzyme to a pharmacological target. However, despite our extensive current knowledge about AMPK, the growing community is busier than ever. This book provides a snapshot of recent and current AMPK research with an emphasis on work providing molecular insight, including but not limited to novel physiological and pathological functions, or regulatory mechanisms. Up-to-date reviews and research articles are included.
n/a --- HDACs --- transcription --- epigenetics --- spermatozoa --- par complex --- A769662 --- MDCK --- skeletal muscle --- AID --- phosphorylation --- energy metabolism --- monocytes --- autophagy --- CML --- liver --- hindlimb suspension --- pregnancy --- preeclampsia --- gestational diabetes mellitus --- CaMKK2 --- assisted reproduction techniques --- nutrient-sensing signals --- sonic hedgehog --- protein acetylation --- glycogen storage disease --- AMPK --- adenosine monophosphate-activated protein kinase --- AICAR --- indirect calorimetry --- IL-1? --- MyHC I(?) --- HDAC4/5 --- endothelial cells --- infection --- hepatocyte --- p70S6K --- lipid metabolism --- host defense --- exercise --- kidney disease --- heat shock protein --- ?RIM --- mycobacteria --- activation loop --- developmental origins of health and disease (DOHaD) --- CREB --- TAK1 --- metabolic-inflammation --- phenylephrine --- AMP-activated protein kinase (AMPK) --- KATs --- 2-methoxyestradiol --- DNA methylation --- NLRP3 --- pump --- ?-linker --- steatosis --- AMPK kinase --- stress --- endothelial nitric-oxide synthase --- vasodilation --- adherent junctions --- epithelial cells --- glycogen --- Akt --- synaptic activation --- cellular energy sensing --- glucose uptake --- transporter --- co-expression --- atrophy --- nutrigenomics --- motility --- vasoconstriction --- fatty acid oxidation --- oxidative stress --- AS160 --- membrane --- histone modification --- sirtuin 1 (SIRT1) --- chromatin remodeling --- insulin signalling --- dietary fatty acids --- ULK --- CMML --- adaptive thermogenesis --- mTOR --- MDS --- mechanical unloading --- AML --- endothelial function --- medulloblastoma --- PKA --- adipose tissue --- NAD+ --- membranes --- nutrition --- ZO-1 --- TBC1D4 --- adipocyte --- soluble Adenylyl cyclase --- metabolism --- renin-angiotensin system --- energy utilization --- proteasome --- differentiation --- signaling --- peroxisome proliferator-activated receptor gamma coactivator 1-? (PGC1?) --- hypertrophy --- AMP-activated protein kinase --- metabolic disease --- LKB1 --- soleus muscle --- macrophages --- Immediate early genes --- CBS --- beiging --- motor endplate remodeling --- ionomycin --- nectin-afadin --- tight junctions --- resveratrol --- protein kinase B --- regrowth --- mitochondria --- protein synthesis --- energy deficiency --- catechol-O-methyltransferase --- fiber-type --- microarrays --- carrier --- acetyl-CoA --- hypertension --- 3T3-L1 --- hypothalamus --- food intake --- benign
Choose an application
Starting from a kinase of interest, AMP-activated protein kinase (AMPK) has gone far beyond an average biomolecule. Being expressed in all mammalian cell types and probably having a counterpart in every eukaryotic cell, AMPK has attracted interest in virtually all areas of biological research. Structural and biophysical insights have greatly contributed to a molecular understanding of this kinase. From good old protein biochemistry to modern approaches, such as systems biology and advanced microscopy, all disciplines have provided important information. Thus, multiple links to cellular events and subcellular localizations have been established. Moreover, the crucial involvement of AMPK in human health and disease has been evidenced. AMPK accordingly has moved from an interesting enzyme to a pharmacological target. However, despite our extensive current knowledge about AMPK, the growing community is busier than ever. This book provides a snapshot of recent and current AMPK research with an emphasis on work providing molecular insight, including but not limited to novel physiological and pathological functions, or regulatory mechanisms. Up-to-date reviews and research articles are included.
HDACs --- transcription --- epigenetics --- spermatozoa --- par complex --- A769662 --- MDCK --- skeletal muscle --- AID --- phosphorylation --- energy metabolism --- monocytes --- autophagy --- CML --- liver --- hindlimb suspension --- pregnancy --- preeclampsia --- gestational diabetes mellitus --- CaMKK2 --- assisted reproduction techniques --- nutrient-sensing signals --- sonic hedgehog --- protein acetylation --- glycogen storage disease --- AMPK --- adenosine monophosphate-activated protein kinase --- AICAR --- indirect calorimetry --- IL-1? --- MyHC I(?) --- HDAC4/5 --- endothelial cells --- infection --- hepatocyte --- p70S6K --- lipid metabolism --- host defense --- exercise --- kidney disease --- heat shock protein --- ?RIM --- mycobacteria --- activation loop --- developmental origins of health and disease (DOHaD) --- CREB --- TAK1 --- metabolic-inflammation --- phenylephrine --- AMP-activated protein kinase (AMPK) --- KATs --- 2-methoxyestradiol --- DNA methylation --- NLRP3 --- pump --- ?-linker --- steatosis --- AMPK kinase --- stress --- endothelial nitric-oxide synthase --- vasodilation --- adherent junctions --- epithelial cells --- glycogen --- Akt --- synaptic activation --- cellular energy sensing --- glucose uptake --- transporter --- co-expression --- atrophy --- nutrigenomics --- motility --- vasoconstriction --- fatty acid oxidation --- oxidative stress --- AS160 --- membrane --- histone modification --- sirtuin 1 (SIRT1) --- chromatin remodeling --- insulin signalling --- dietary fatty acids --- ULK --- CMML --- adaptive thermogenesis --- mTOR --- MDS --- mechanical unloading --- AML --- endothelial function --- medulloblastoma --- PKA --- adipose tissue --- NAD+ --- membranes --- nutrition --- ZO-1 --- TBC1D4 --- adipocyte --- soluble Adenylyl cyclase --- metabolism --- renin-angiotensin system --- energy utilization --- proteasome --- differentiation --- signaling --- peroxisome proliferator-activated receptor gamma coactivator 1-? (PGC1?) --- hypertrophy --- AMP-activated protein kinase --- metabolic disease --- LKB1 --- soleus muscle --- macrophages --- Immediate early genes --- CBS --- benign --- motor endplate remodeling --- ionomycin --- nectin-afadin --- tight junctions --- resveratrol --- protein kinase B --- regrowth --- mitochondria --- protein synthesis --- energy deficiency --- catechol-O-methyltransferase --- fiber-type --- microarrays --- carrier --- acetyl-CoA --- hypertension --- 3T3-L1 --- hypothalamus --- food intake --- HDACs --- transcription --- epigenetics --- spermatozoa --- par complex --- A769662 --- MDCK --- skeletal muscle --- AID --- phosphorylation --- energy metabolism --- monocytes --- autophagy --- CML --- liver --- hindlimb suspension --- pregnancy --- preeclampsia --- gestational diabetes mellitus --- CaMKK2 --- assisted reproduction techniques --- nutrient-sensing signals --- sonic hedgehog --- protein acetylation --- glycogen storage disease --- AMPK --- adenosine monophosphate-activated protein kinase --- AICAR --- indirect calorimetry --- IL-1? --- MyHC I(?) --- HDAC4/5 --- endothelial cells --- infection --- hepatocyte --- p70S6K --- lipid metabolism --- host defense --- exercise --- kidney disease --- heat shock protein --- ?RIM --- mycobacteria --- activation loop --- developmental origins of health and disease (DOHaD) --- CREB --- TAK1 --- metabolic-inflammation --- phenylephrine --- AMP-activated protein kinase (AMPK) --- KATs --- 2-methoxyestradiol --- DNA methylation --- NLRP3 --- pump --- ?-linker --- steatosis --- AMPK kinase --- stress --- endothelial nitric-oxide synthase --- vasodilation --- adherent junctions --- epithelial cells --- glycogen --- Akt --- synaptic activation --- cellular energy sensing --- glucose uptake --- transporter --- co-expression --- atrophy --- nutrigenomics --- motility --- vasoconstriction --- fatty acid oxidation --- oxidative stress --- AS160 --- membrane --- histone modification --- sirtuin 1 (SIRT1) --- chromatin remodeling --- insulin signalling --- dietary fatty acids --- ULK --- CMML --- adaptive thermogenesis --- mTOR --- MDS --- mechanical unloading --- AML --- endothelial function --- medulloblastoma --- PKA --- adipose tissue --- NAD+ --- membranes --- nutrition --- ZO-1 --- TBC1D4 --- adipocyte --- soluble Adenylyl cyclase --- metabolism --- renin-angiotensin system --- energy utilization --- proteasome --- differentiation --- signaling --- peroxisome proliferator-activated receptor gamma coactivator 1-? (PGC1?) --- hypertrophy --- AMP-activated protein kinase --- metabolic disease --- LKB1 --- soleus muscle --- macrophages --- Immediate early genes --- CBS --- benign --- motor endplate remodeling --- ionomycin --- nectin-afadin --- tight junctions --- resveratrol --- protein kinase B --- regrowth --- mitochondria --- protein synthesis --- energy deficiency --- catechol-O-methyltransferase --- fiber-type --- microarrays --- carrier --- acetyl-CoA --- hypertension --- 3T3-L1 --- hypothalamus --- food intake
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The adipokine adiponectin is very concentrated in plasma, and decreased levels of adiponectin are associated with pathological conditions such as obesity, diabetes, cardiovascular diseases, and metabolic syndrome. When produced in its full-length form, adiponectin self-associates to generate multimeric complexes. The full-length form of adiponectin can be cleaved by the globular form of elastase that is produced locally, and the resulting biological effects are exerted in a paracrine or autocrine manner. The different forms of adiponectin bind to specific receptors consisting of two G-protein-independent, seven-transmembrane-spanning receptors, called AdipoR1 and AdipoR2, while T-cadherin has been identified as a potential receptor for high molecular weight complexes of adiponectin. Adiponectin exerts a key role in cellular metabolism, regulating glucose levels as well as fatty acid breakdown. However, its biological effects are heterogeneous, involving multiple target tissues. The Special Issue “Mechanisms of Adiponectin Action” highlights the pleiotropic role of this hormone through 3 research articles and 7 reviews. These papers focus on the recent knowledge regarding adiponectin in different target tissues, both in healthy and in diseased conditions.
acidic and rich in cysteine (SPARC) --- n/a --- regeneration --- fertility --- pig --- endocrine cancer --- NGF? --- reproductive tract --- neuritogenesis --- skeletal muscle --- matricellular proteins --- adiponectin isoforms --- obesity --- atherosclerosis --- hair growth-related factor --- ovarian cancer --- adipose tissue --- AdipoRon --- extracellular signal-regulated kinase (ERK) --- PC12 cells --- endometrial cancer --- AMPK --- metabolism --- adiponectin --- transcriptome --- exercise --- training --- inflammation --- BIAcore --- muscle --- adipokines --- human follicular dermal papilla cell --- estrogen receptor --- endometrium --- adiponectin inducer --- breast cancer --- implantation --- microarray --- Secreted protein --- adipogenesis --- kojyl cinnamate ester derivative --- cell signaling --- lipotoxicity --- cervix cancer --- cancer --- cholesterol efflux --- myopathies --- diabetes
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ROS were long considered one of the key players in tissue injury. Indeed, overproduction of ROS results in oxidative stress, a process leading to the development of many pathological conditions. For the treatment of these conditions, the use of antioxidants was proposed. Over time, it was shown that ROS at low concentrations act as signaling molecules, leading to the regulation of physiological functions. Moreover, several interventions that increase ROS generation activate stress-adaptive responses that extend the lifespan. It was also shown that excessive use of antioxidants can counter the beneficial effects of ROS. Currently, much progress has been made in understanding the role of ROS in human diseases and aging, as well as in the regulation of physiological functions, and in identifying the signaling pathways involved in ROS. However, much remains to be understood about the mutual interactions among signaling pathways underlying organisms’ adaptive responses, their modifications (which occur during aging), and some disease states. The aim of this Special Issue is to underline the effects of ROS production and antioxidant treatment in living organisms, focusing on their impact on health, disease, and aging.
CTCL --- apoptosis --- cell viability --- c-FLIP --- XIAP --- artemisinin --- SH-SY5Y cells --- hippocampal neurons --- H2O2 --- AMPK pathway --- atherosclerosis --- sphingomyelin synthase 2 --- endothelial dysfunction --- endoplasmic reticulum stress --- β-catenin --- insulin resistance --- cancer --- cardiovascular disease --- neurodegenerative disorders --- exercise --- mitochondria --- oxidative stress --- PGC-1 --- Nrf2 --- UCPs --- ROS --- light --- DNA damage --- evolution --- D-box --- cavefish --- Spalax --- trimethylamine N-oxide --- cardiomyocytes --- cardiotoxicity --- mitochondrial membrane potential --- CORM-2 --- NADPH oxidase --- AP-1 --- HO-1 --- Renal cell carcinoma (RCC) --- reactive oxygen species (ROS) --- glutathione (GSH) metabolism --- cancer therapy --- clear cell RCC --- papillary RCC --- chromophobe RCC --- sarcopenia --- reactive oxygen species --- redox signaling --- antioxidant supplementation --- protein aggregation --- redox --- proteinopathy --- peroxiredoxins --- tumorigenesis --- ROS scavengers --- n/a
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The focus of this Special Issue is “Nutrition and the Central Nervous System”. The brain is, as a very specialized and one of the most metabolically active organs of the body, dependent on a steady and sufficient supply of dietary ingredients. The critical role of the diet for brain development as well as for proper CNS functioning and the possible preventative roles against neurodegenerative and neurological conditions is commonly accepted. The overarching aim of this Special Issue is pinpointing the mechanisms of action and publishing state-of-the-art contributions discussing the roles that nutritional compounds play in the development, maintenance, and aging of the CNS.
dipeptide --- dopamine --- hippocampus --- memory --- monoamine oxidase B --- milk --- hypothalamus --- nucleus accumbens --- reward --- appetite --- palatability --- major depressive disorder --- Chinese herbal formula --- corticosterone --- BDNF --- oxidative stress --- probiotics --- microbiota --- beneficial bacteria --- psychobiotics --- human health --- neurodegenerative diseases --- neuroinflammation --- apoptosis --- synaptic dysfunction --- IRS1 --- serine phosphorylation --- diabetes --- aging --- Alzheimer’s disease --- memory decline --- Aβ --- AMPK --- energy depletion --- S-equol --- 17β-estradiol --- estrogen receptor alpha --- cell cycle --- β-Amyloid --- microbiome --- microbiota-gut-brain axis --- ADHD --- attention-deficit-hyperactive-disorder --- Angelica gigas --- mild cognitive impairment --- traumatic brain injury --- chronic mild stress --- children --- cingulum --- development --- dietary sugar --- fructose
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Autophagy (“auto-digestion”), a lysosome-dependent process, degrades and turns over damaged or senescent organelles and proteins. Autophagy is a highly regulated process that impacts several vital cellular responses, including inflammation, cell death, energy metabolism, and homeostasis of organelles (mitochondria and others). Although the role of autophagy in the maintenance of tissue homeostasis is well documented, its role during tissue injury and regeneration is still emerging. In this Special Issue on “Autophagy in Tissue Injury and Homeostasis”, we focus on the roles of autophagy in systemic, specific tissue (organs/cells) injury or organ failure associated with sepsis, inflammation, metabolic disorder, toxic chemicals, ischemia-reperfusion injury, hypoxic oxidative stress, tissue fibrosis, trauma, and nutrient starvation. The knowledge gained from the identification and characterization of new molecular mechanisms will shed light on biomedical applications for tissue protection through the modulation of autophagy.
Medicine --- aging --- dietary restriction --- acute kidney injury --- mitochondria --- autophagy --- mitophagy --- ischemia --- renal tubular cells --- diabetic nephropathy --- exosomes --- mTOR --- innate immunity --- immune cell --- inflammasome --- Paneth cell --- inflammatory bowel disease --- Crohn's disease --- hepatocytes --- hepatic stellate cells --- sinusoidal endothelial cells --- macrophages --- fibrosis --- cirrhosis --- hepatocellular carcinoma --- biomarkers --- cell death --- glutaminase --- metabolism --- molecular rehabilitation. --- kidney diseases --- oxidative stress --- inflammation --- ATGs --- intestinal homeostasis --- inflammatory bowel diseases --- HCC therapy --- Autophagy --- acute lung injury --- idiopathic pulmonary fibrosis --- COPD --- tuberculosis --- PAH --- cystic fibrosis --- Beclin-1 --- cardiac dysfunction --- sepsis --- endotoxemia --- muscle regeneration --- stem cell --- immune --- macrophage --- senescence --- exercise --- caloric restriction --- diabetic retinopathy --- PINK1 --- Notoginsenoside R1 --- ethanol --- LC3 --- apoptosis --- Sertoli cell --- Parkin --- TFEB --- infertility --- AMPK --- FOXO --- MTOR --- parkin --- spinal cord injury --- traumatic brain injury --- autophagic flux --- neuronal cell death --- lysosomal damage --- aging --- dietary restriction --- acute kidney injury --- mitochondria --- autophagy --- mitophagy --- ischemia --- renal tubular cells --- diabetic nephropathy --- exosomes --- mTOR --- innate immunity --- immune cell --- inflammasome --- Paneth cell --- inflammatory bowel disease --- Crohn's disease --- hepatocytes --- hepatic stellate cells --- sinusoidal endothelial cells --- macrophages --- fibrosis --- cirrhosis --- hepatocellular carcinoma --- biomarkers --- cell death --- glutaminase --- metabolism --- molecular rehabilitation. --- kidney diseases --- oxidative stress --- inflammation --- ATGs --- intestinal homeostasis --- inflammatory bowel diseases --- HCC therapy --- Autophagy --- acute lung injury --- idiopathic pulmonary fibrosis --- COPD --- tuberculosis --- PAH --- cystic fibrosis --- Beclin-1 --- cardiac dysfunction --- sepsis --- endotoxemia --- muscle regeneration --- stem cell --- immune --- macrophage --- senescence --- exercise --- caloric restriction --- diabetic retinopathy --- PINK1 --- Notoginsenoside R1 --- ethanol --- LC3 --- apoptosis --- Sertoli cell --- Parkin --- TFEB --- infertility --- AMPK --- FOXO --- MTOR --- parkin --- spinal cord injury --- traumatic brain injury --- autophagic flux --- neuronal cell death --- lysosomal damage
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ROS were long considered one of the key players in tissue injury. Indeed, overproduction of ROS results in oxidative stress, a process leading to the development of many pathological conditions. For the treatment of these conditions, the use of antioxidants was proposed. Over time, it was shown that ROS at low concentrations act as signaling molecules, leading to the regulation of physiological functions. Moreover, several interventions that increase ROS generation activate stress-adaptive responses that extend the lifespan. It was also shown that excessive use of antioxidants can counter the beneficial effects of ROS. Currently, much progress has been made in understanding the role of ROS in human diseases and aging, as well as in the regulation of physiological functions, and in identifying the signaling pathways involved in ROS. However, much remains to be understood about the mutual interactions among signaling pathways underlying organisms’ adaptive responses, their modifications (which occur during aging), and some disease states. The aim of this Special Issue is to underline the effects of ROS production and antioxidant treatment in living organisms, focusing on their impact on health, disease, and aging.
Research & information: general --- Biology, life sciences --- CTCL --- apoptosis --- cell viability --- c-FLIP --- XIAP --- artemisinin --- SH-SY5Y cells --- hippocampal neurons --- H2O2 --- AMPK pathway --- atherosclerosis --- sphingomyelin synthase 2 --- endothelial dysfunction --- endoplasmic reticulum stress --- β-catenin --- insulin resistance --- cancer --- cardiovascular disease --- neurodegenerative disorders --- exercise --- mitochondria --- oxidative stress --- PGC-1 --- Nrf2 --- UCPs --- ROS --- light --- DNA damage --- evolution --- D-box --- cavefish --- Spalax --- trimethylamine N-oxide --- cardiomyocytes --- cardiotoxicity --- mitochondrial membrane potential --- CORM-2 --- NADPH oxidase --- AP-1 --- HO-1 --- Renal cell carcinoma (RCC) --- reactive oxygen species (ROS) --- glutathione (GSH) metabolism --- cancer therapy --- clear cell RCC --- papillary RCC --- chromophobe RCC --- sarcopenia --- reactive oxygen species --- redox signaling --- antioxidant supplementation --- protein aggregation --- redox --- proteinopathy --- peroxiredoxins --- tumorigenesis --- ROS scavengers --- CTCL --- apoptosis --- cell viability --- c-FLIP --- XIAP --- artemisinin --- SH-SY5Y cells --- hippocampal neurons --- H2O2 --- AMPK pathway --- atherosclerosis --- sphingomyelin synthase 2 --- endothelial dysfunction --- endoplasmic reticulum stress --- β-catenin --- insulin resistance --- cancer --- cardiovascular disease --- neurodegenerative disorders --- exercise --- mitochondria --- oxidative stress --- PGC-1 --- Nrf2 --- UCPs --- ROS --- light --- DNA damage --- evolution --- D-box --- cavefish --- Spalax --- trimethylamine N-oxide --- cardiomyocytes --- cardiotoxicity --- mitochondrial membrane potential --- CORM-2 --- NADPH oxidase --- AP-1 --- HO-1 --- Renal cell carcinoma (RCC) --- reactive oxygen species (ROS) --- glutathione (GSH) metabolism --- cancer therapy --- clear cell RCC --- papillary RCC --- chromophobe RCC --- sarcopenia --- reactive oxygen species --- redox signaling --- antioxidant supplementation --- protein aggregation --- redox --- proteinopathy --- peroxiredoxins --- tumorigenesis --- ROS scavengers
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In this book, we collected scientific articles, including reviews and research articles, showcasing the lastest literature on the importance of biochemical biomarkers in the management of neurodegenerative diseases, from screening to diagnosis, prognosis, and treatment.
Medicine --- Neurosciences --- GLUT3 --- cerebral ischemia --- MCAO --- resveratrol --- astrocytes --- AMPK --- amyotrophic lateral sclerosis --- GSK3β --- neurodegenerative disease --- PD --- Arylsulfatase A --- lysosomes --- GWAS --- Gaucher's disease --- prognostic biomarker --- focused ultrasound --- MR-guided focused ultrasound --- high-intensity focused ultrasound ablation --- magnetic resonance imaging --- image quality --- stereotaxic techniques --- essential tremor --- Alzheimer's disease --- amyloid precursor protein --- Tyr682 residue --- YENPTY motif --- Fyn tyrosine kinase --- amyloid beta --- ALS --- biomarker --- beta amyloid --- AD --- biomarkers --- SARS-CoV-2 --- neuroinflammation --- neurodegenerative nisease --- nervous system --- Alzheimer's Disease --- Vitamin D --- 25(OH)D levels --- Vitamin D deficiency --- inherited neuromuscular disorders --- rare diseases --- multiple sclerosis --- genetic --- polymorphisms --- FOXP3 --- GATA3 --- vitamin D --- neuromelanin --- nigrosome-1 --- iron --- radiomics --- neurodegenerative diseases --- Parkinson's disease --- parkinsonian disorders --- GLUT3 --- cerebral ischemia --- MCAO --- resveratrol --- astrocytes --- AMPK --- amyotrophic lateral sclerosis --- GSK3β --- neurodegenerative disease --- PD --- Arylsulfatase A --- lysosomes --- GWAS --- Gaucher's disease --- prognostic biomarker --- focused ultrasound --- MR-guided focused ultrasound --- high-intensity focused ultrasound ablation --- magnetic resonance imaging --- image quality --- stereotaxic techniques --- essential tremor --- Alzheimer's disease --- amyloid precursor protein --- Tyr682 residue --- YENPTY motif --- Fyn tyrosine kinase --- amyloid beta --- ALS --- biomarker --- beta amyloid --- AD --- biomarkers --- SARS-CoV-2 --- neuroinflammation --- neurodegenerative nisease --- nervous system --- Alzheimer's Disease --- Vitamin D --- 25(OH)D levels --- Vitamin D deficiency --- inherited neuromuscular disorders --- rare diseases --- multiple sclerosis --- genetic --- polymorphisms --- FOXP3 --- GATA3 --- vitamin D --- neuromelanin --- nigrosome-1 --- iron --- radiomics --- neurodegenerative diseases --- Parkinson's disease --- parkinsonian disorders
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The focus of this Special Issue is “Nutrition and the Central Nervous System”. The brain is, as a very specialized and one of the most metabolically active organs of the body, dependent on a steady and sufficient supply of dietary ingredients. The critical role of the diet for brain development as well as for proper CNS functioning and the possible preventative roles against neurodegenerative and neurological conditions is commonly accepted. The overarching aim of this Special Issue is pinpointing the mechanisms of action and publishing state-of-the-art contributions discussing the roles that nutritional compounds play in the development, maintenance, and aging of the CNS.
Research & information: general --- Biology, life sciences --- Food & society --- dipeptide --- dopamine --- hippocampus --- memory --- monoamine oxidase B --- milk --- hypothalamus --- nucleus accumbens --- reward --- appetite --- palatability --- major depressive disorder --- Chinese herbal formula --- corticosterone --- BDNF --- oxidative stress --- probiotics --- microbiota --- beneficial bacteria --- psychobiotics --- human health --- neurodegenerative diseases --- neuroinflammation --- apoptosis --- synaptic dysfunction --- IRS1 --- serine phosphorylation --- diabetes --- aging --- Alzheimer’s disease --- memory decline --- Aβ --- AMPK --- energy depletion --- S-equol --- 17β-estradiol --- estrogen receptor alpha --- cell cycle --- β-Amyloid --- microbiome --- microbiota-gut-brain axis --- ADHD --- attention-deficit-hyperactive-disorder --- Angelica gigas --- mild cognitive impairment --- traumatic brain injury --- chronic mild stress --- children --- cingulum --- development --- dietary sugar --- fructose --- dipeptide --- dopamine --- hippocampus --- memory --- monoamine oxidase B --- milk --- hypothalamus --- nucleus accumbens --- reward --- appetite --- palatability --- major depressive disorder --- Chinese herbal formula --- corticosterone --- BDNF --- oxidative stress --- probiotics --- microbiota --- beneficial bacteria --- psychobiotics --- human health --- neurodegenerative diseases --- neuroinflammation --- apoptosis --- synaptic dysfunction --- IRS1 --- serine phosphorylation --- diabetes --- aging --- Alzheimer’s disease --- memory decline --- Aβ --- AMPK --- energy depletion --- S-equol --- 17β-estradiol --- estrogen receptor alpha --- cell cycle --- β-Amyloid --- microbiome --- microbiota-gut-brain axis --- ADHD --- attention-deficit-hyperactive-disorder --- Angelica gigas --- mild cognitive impairment --- traumatic brain injury --- chronic mild stress --- children --- cingulum --- development --- dietary sugar --- fructose
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